Delivery of respiratory therapy using conduits with varying wall thicknesses

ABSTRACT

An air delivery system for providing a supply of air from a source of air at positive pressure to an interfacing structure located at the entrance to the airways of a patient includes a manifold adapted to connect with the supply of positive air pressure and at least one tube connected to the manifold and adapted to deliver the supply of air to the interfacing structure. Each tube is structured to allow movement between an open phase in which the tube allows the passage of air and a collapsed phase in which the tube is collapsed. Each tube is structured such that weight of a typical patient&#39;s head against bedding apparel is sufficient to collapse the tube from the open phase to the collapsed phase.

CROSS-REFERENCE TO APPLICATION

This application is a continuation of U.S. application Ser. No. 15/650,577, filed Jul. 14, 2017, which was a continuation of U.S. application Ser. No. 12/085,191, filed Apr. 16, 2009, which was the U.S. national phase of International Application No. PCT/AU2007/001051, filed Jul. 27, 2007, which designated the U.S. and claimed the benefit of U.S. Provisional Application Nos. 60/833,841, filed Jul. 28, 2006, 60/874,968, filed Dec. 15, 2006, 60/924,241, filed May 4, 2007, and 60/929,393, filed Jun. 25, 2007, each of which is hereby incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The invention relates to the delivery of respiratory therapy to a patient. Examples of such therapies are Continuous Positive Airway Pressure (CPAP) treatment, Non-Invasive Positive Pressure Ventilation (NIPPV), and Variable Positive Airway Pressure (VPAP). The therapy is used for treatment of various respiratory conditions including Sleep Disordered Breathing (SDB) and more particularly Obstructive Sleep Apnea (OSA).

BACKGROUND OF THE INVENTION

Typically, respiratory therapy is delivered in the form of a mask system positioned between a patient and apparatus providing a supply of pressurized air or breathing gas. Mask systems in the field of the invention differ from mask systems used in other applications such as aviation and safety in particular because of their emphasis on comfort. This high level of comfort is desired because patients must sleep wearing the masks for hours, possibly every night for the rest of their lives. In addition, therapy compliance can be improved if the patient's bed partner is not adversely affected by the patient's therapy and wearing of the mask generally.

Mask systems typically have a highly clinical aesthetic (as will be described below). This can lead to patients becoming embarrassed about their therapy since the clinical aesthetic serves as a blatant reminder that they are ill and consequently can leave a negative perception of the patient in the mind of an observer.

Mask systems typically, although not always, comprise (i) a rigid or semi-rigid portion often referred to as a shell or frame, (ii) a soft, patient contacting portion often referred to as a cushion, and (iii) some form of headgear to hold the frame and cushion in position. If the mask system does in fact include multiple components, at least some assembly and adjustment may be required, which can be difficult for patients who may suffer from lack of dexterity, etc. Further, mask systems often include a mechanism for connecting an air delivery conduit. The air delivery conduit is usually connected to a blower or flow generator.

Patient contacting portions, e.g., cushions, are typically constructed of a silicone material, but patient contacting portions including foam are known. For example, U.S. Pat. No. 5,429,683 discloses a lining for a mask made of a polyurethane foam covered with skin (e.g., latex or silicone). However, skinned foam does not allow the portion in contact with the face to breathe, which can lead to skin irritation, and the sealing portion may be subject to creasing which may cause discomfort and lead to leak. The skin can also feel too hard for some patients, depending on the thickness and support structure. The skin also does not allow a high degree of local deformation and may be subject to tension transfer across its surface, which can result in shifting of the mask on the face and loss of seal/comfort.

A range of mask systems are known including nasal masks, nose & mouth masks, full face masks and nasal prongs, pillows, nozzles & cannulae. Masks typically cover more of the face than nasal prongs, pillows, nozzles and cannulae. Nasal prongs, nasal pillows, nozzles and cannulae all will be collectively referred to as nasal prongs.

There is a continuous need in the art to provide mask systems with a high level of comfort and usability and a newly perceived need to provide mask systems having improved aesthetics (i.e., less clinical and bulky).

SUMMARY OF THE INVENTION

One aspect of the present invention is to provide a therapy compliance-enhancing patient interface.

Another aspect of the present invention is to provide a comfortable patient interface.

Another aspect of the invention is to provide a patient interface having a non-medical appearance. In one form, this may be achieved by creating a soft, comfortable, flexible patient interface that has the appearance of an article of clothing.

Another aspect of the invention relates to a comfortable, unobtrusive, easy to use, stable system for delivering a supply of air at positive pressure to the entrance to the patient's airways such as may be used in nasal CPAP treatment of sleep disordered breathing. This system is compatible with a range of interfaces and/or sealing structures, including nasal masks, nasal cushions, mouth masks, etc. The system has been particularly designed so that a patient may comfortably sleep in a range of different positions, including rolling onto the side of their face, without experiencing discomfort and while maintaining adequate therapy. This system offers a number of improvements over the prior art.

Another aspect of the invention relates to an interfacing structure that provides improved comfort, enhanced interfacing performance, and ease of use over prior sealing structures. Aspects of the improved interfacing structure are that it requires less precise fitting than prior sealing structures and does so with a more comfortable and even pressure distribution on the patient's face. The interfacing structure has a more natural feel against the skin than prior sealing structures and also features controlled air permeability so that the skin is allowed to breathe. Another aspect of the improved interfacing structure is that it is less prone to disruption by movement than prior sealing structures.

Another aspect of the invention relates to an air delivery system for providing a supply of air from a source of air at positive pressure to an interfacing structure located at the entrance to the airways of a patient. The air delivery system includes a manifold adapted to be connected with the supply of positive air pressure and at least one tube connected to the manifold and is adapted to deliver the supply of air to the interfacing structure. Each tube is structured to allow movement between (1) an open phase in which the tube allows the passage of air and (2) a collapsed phase in which the tube is collapsed. Each tube is structured such that weight of a typical patient's head against bedding apparel (e.g., pillow) is sufficient to collapse the tube from the open phase to the collapsed phase.

Another aspect of the invention relates to an air conduit or tube that is comfortable to lie on because: when you lie on the conduit, the part that you lie on squashes flat or substantially flat; the conduit is generally sufficiently thin so that you can lie on it; and/or the conduit does not need to flatten because it is already sufficiently comfortable.

Another aspect of the invention relates to a system of air conduits having sufficient redundancy that if some or one of the conduits is occluded, the system retains sufficient flow of air at therapeutic pressure.

Another aspect of the invention relates to an air delivery system adapted to provide a therapeutic supply of air at pressure when a portion is being lain on by the patient.

Another aspect of the invention relates to an air delivery system for providing a supply of air from a source of air at positive pressure to an interfacing structure located at the entrance to the airways of a patient. The air delivery system includes a manifold adapted to connect with the supply of positive air pressure and at least one tube connected to the manifold, the tube being adapted to deliver the supply of air to the interfacing structure. The manifold is adapted to be positioned on or in front of a crown of the patient's head in use.

Another aspect of the invention relates to an air delivery and stabilizing system for providing a supply of air from a source of air at positive pressure to an interfacing structure located at the entrance to the airways of a patient. The air delivery system includes a manifold adapted to connect with the supply of positive air pressure, a pair of tubes connected to the manifold and adapted to deliver the supply of air to the interfacing structure, a rigidizing element provided to each tube to add rigidity to the tube, and a back strap provided to the tubes and/or rigidizing elements and adapted to engage the back of the patient's head. Each tube is adapted to extend from a respective side of the manifold at or in front of the crown of the patient's head, along a respective side of the patient's face between the patient's eye and ear, and under the patient's nose.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient including a support structure adapted to be coupled to an air delivery system that provides a supply of air from a source of air at positive pressure and an interface provided to the support structure. The interface is constructed of a soft viscoelastic foam and adapted to contact with surfaces of the patient's face and nose in use.

Another aspect of the invention relates to a patient interface including a first loop and a second loop connected to the first loop. The first loop is adapted to pass along an underside of the patient's nose, along the cheek region, above the ears, and over the crown of the patient's head to define a sealing force against the underside of the patient's nose in use. The second loop is adapted to pass generally over the occipital bone to define a headgear vector at an angle between 40°-80° with the first loop.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient. The interfacing structure includes an interface adapted to contact with skin surfaces under the patient's nose in use, wherein the interface has a thickness of about 5-50 mm.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient. The interfacing structure includes an interface adapted to contact with skin surfaces under the patient's nose in use, wherein the interface includes an unskinned surface on surfaces for interfacing or contacting the patient's skin in use.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient. The interfacing structure includes an interface adapted to contact with skin surfaces under the patient's nose in use, wherein the interface includes sufficient softness and compliance in a direction normal to the patient's face to conform to the facial anatomy that it is interfacing with.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient. The interfacing structure includes an interface adapted to contact with skin surfaces under the patient's nose in use, wherein the interface is constructed of breathable or permeable material.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient. The interfacing structure includes an interface constructed of foam and adapted to contact with skin surfaces under the patient's nose in use, wherein the interface is adapted to provide a compressive force to seal against the patient's skin in use.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient. The interfacing structure includes an interface adapted to contact with skin surfaces under the patient's nose in use, wherein the interface has a textured surface.

Another aspect of the invention relates to an interfacing structure located at an entrance to the airways of a patient. The interfacing structure includes an interface adapted to contact with skin surfaces under the patient's nose in use, wherein the interface includes a rate of return of less than about 5 cm/sec.

Another aspect of the invention relates to an air delivery system for providing a supply of air from a source of air at positive pressure to a patient. The air delivery system includes an interfacing structure located at the entrance to the airways of the patient and a pair of tubes adapted to extend along a respective side of the patient's face and deliver the supply of air to the interfacing structure. Each tube has at least one portion that is structured to allow movement between (1) an open phase in which the tube allows the flow of air without undue resistance and (2) at least a partially collapsed phase in which the tube is at least partially collapsed to restrict or prevent the flow of air. Each tube is structured such that it is comfortable to lie on.

Another aspect relates to a gas delivery system for providing a supply of gas from a source of gas at positive pressure to an interfacing structure located at an entrance to the airways of a patient. The gas delivery system includes at least two gas passages adapted to be in communication with the source of gas to deliver the supply of gas to the interfacing structure. The at least two gas passages are structured and configured to cooperate such that an adequate supply of gas is delivered to the interfacing structure even if one of the gas passages assumes a collapsed configuration to prevent or substantially impede the flow of air.

Other aspects, features, and advantages of this invention will become apparent from the following detailed description when taken in conjunction with the accompanying drawings, which are a part of this disclosure and which illustrate, by way of example, principles of this invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings facilitate an understanding of various embodiments of this invention. In such drawings:

FIGS. 1-1 to 1-16 are various views of a patient interface according to an embodiment of the present invention;

FIGS. 2-1 to 2-2 are schematic views illustrating assembly of a patient interface according to an embodiment of the present invention;

FIG. 2-3 is a schematic view illustrating attachment of a patient interface to a PAP device according to an embodiment of the present invention;

FIGS. 2-4 a to 2-4 b illustrate attachment of a patient interface to a PAP device according to another embodiment of the present invention;

FIGS. 3-1, 3-2 a, and 3-2 b illustrate a tube of a patient interface in open and collapsed phases according to an embodiment of the present invention;

FIG. 3-3 is a schematic view of a tube and rigidizing element of a patient interface according to an embodiment of the present invention;

FIGS. 3-4 and 3-4 a to 3-4 f illustrate various cross-sections of a tube along its length according to an embodiment of the present invention;

FIGS. 3-5 a to 3-5 c are schematic views of a tube of a patient interface in open and collapsed or partially collapsed phases according to another embodiment of the present invention;

FIGS. 3-6 a to 3-6 b illustrate a tube having a concertina configuration according to another embodiment of the present invention;

FIGS. 4-1 to 4-5 illustrate tubing for a patient interface according to an embodiment of the present invention;

FIGS. 4-6 to 4-9 illustrate tubes and a rigidizing element according to an embodiment of the present invention;

FIGS. 5-1 to 5-3 illustrate tubes of a patient interface according to alternative embodiments of the present invention;

FIGS. 6-1 to 6-4 illustrate a back strap of a patient interface according to an embodiment of the present invention;

FIG. 6-5 illustrates a back strap of a patient interface according to another embodiment of the present invention;

FIGS. 7-1 to 7-2 illustrate manifolds of a patient interface according to alternative embodiments of the present invention;

FIGS. 8-1 to 8-5 illustrate a tube configuration according to an embodiment of the present invention;

FIG. 8-6 is a schematic view that illustrates a region where tubing may pass according to an embodiment of the present invention;

FIG. 8-7 illustrates an adjustable tube configuration according to another embodiment of the present invention;

FIGS. 9-1 to 9-3 illustrate a method for fitting a patient interface according to an embodiment of the present invention;

FIGS. 10-1 to 10-6 are various views of a patient interface including a cover according to an embodiment of the present invention;

FIG. 11-1 illustrates a valve of a patient interface according to an embodiment of the present invention;

FIGS. 12-1 to 12-3 illustrate clips of a patient interface according to alternative embodiments of the present invention;

FIGS. 13-1 to 13-2 are various views of a foam interface and support according to an embodiment of the present invention;

FIGS. 13-3 and 13-4 are top and side views of a foam interface having a cut, unskinned surface according to an embodiment of the present invention;

FIG. 13-5 is a top view of a foam interface having a skinned surface according to an embodiment of the present invention;

FIG. 13-6 is an enlarged, schematic cross-section of a portion of the foam interface shown in FIG. 13-5;

FIGS. 13-7 a to 13-7 c illustrate foams according to alternative embodiments of the present invention;

FIG. 13-8 is a schematic cross-section of a portion of a foam interface having a skinned surface and a vent according to an embodiment of the present invention;

FIG. 14-1 is a table of mechanical properties of a foam interface according to an embodiment of the present invention;

FIG. 14-2 is a graph illustrating properties of a foam interface according to an embodiment of the present invention;

FIG. 14-3 is a schematic view of a dispenser adapted to dispense individual packages containing a foam interface according to an embodiment of the present invention;

FIGS. 15-1 to 15-2 illustrate front and side cross-sectional views, respectively, of a foam interface according to an embodiment of the present invention;

FIG. 16-1 is a schematic view of a patient interface according to an embodiment of the present invention;

FIGS. 16-2 to 16-3 are schematic views of a frame and force vector according to an embodiment of the present invention;

FIG. 17-1 schematically illustrates layers of an interfacing structure according to an embodiment of the present invention;

FIG. 17-2 illustrates a method of joining an interface to a frame according to an embodiment of the present invention;

FIGS. 17-3A to 17-3C illustrate a mechanical interference type attachment mechanism to removably attach an interfacing structure to a patient interface according to an embodiment of the present invention;

FIGS. 17-4A to 17-4C illustrate a hook and loop type attachment mechanism to removably attach an interfacing structure to a patient interface according to an embodiment of the present invention;

FIGS. 18-1 to 18-3 illustrate a method of joining an under-the-nose interface to a frame according to an embodiment of the present invention;

FIGS. 19-1 to 19-3 are sequential views illustrating a manufacturing process for applying a pressure sensitive adhesive to the back of an under-the-nose interface according to an embodiment of the present invention;

FIGS. 20-1 to 20-3 illustrate a method of joining an under-the-nose interface to a frame according to an embodiment of the present invention;

FIGS. 20-4 to 20-7 are sequential views illustrating a manufacturing process for forming a composite under-the-nose interface according to an embodiment of the present invention;

FIGS. 21-1 to 21-3 illustrate a flexible frame according to an embodiment of the present invention;

FIG. 22-1 illustrate a flexible frame according to another embodiment of the present invention;

FIG. 23-1 illustrates a flexible frame with a spring element according to an embodiment of the present invention;

FIG. 23-2 is a graph for a variable spring element with k values that vary across its length according to an embodiment of the present invention;

FIG. 23-3 illustrates a flexible frame with a spring element according to another embodiment of the present invention;

FIG. 24-1 illustrates a foam interface including a rigidizer that provides venting according to an embodiment of the present invention;

FIG. 25-1 illustrates a patient interface including an under-the-nose interface and a mouth interface according to an embodiment of the present invention;

FIG. 26-1 is a perspective view of a known mask commercially sold by Respironics under the name of ComfortCurve™;

FIGS. 26-2 to 26-10 illustrate improvements and/or alternative arrangements of Respironics' ComfortCurve™ mask according to embodiments of the present invention;

FIG. 27-1 is a perspective view of a known mask commercially sold by Respironics under the name of OptiLife™;

FIGS. 27-2 to 27-7 illustrate improvements and/or alternative arrangements of Respironics' OptiLife™ mask according to embodiments of the present invention;

FIG. 28-1A is a perspective view of a known mask commercially sold by Respironics' under the name of ComfortLite™;

FIG. 28-2A illustrates an improvement and/or alternative arrangement of Respironics' ComfortLite™ mask according to an embodiment of the present invention;

FIG. 28-1B is a perspective view of a known mask commercially sold by Respironics' under the name of ComfortLite™ 2;

FIG. 28-2B illustrates an improvement and/or alternative arrangement of Respironics' ComfortLite™ 2 mask according to an embodiment of the present invention;

FIGS. 29-1 to 29-2 illustrate a known mask commercially sold by Fisher & Paykel under the name of Opus™;

FIGS. 29-3 to 29-9 illustrate improvements and/or alternative arrangements of Fisher & Paykel's Opus™ mask according to embodiments of the present invention;

FIGS. 30-1 to 30-2 are perspective views of a known mask commercially sold by Puritan Bennett under the name of Breeze® SleepGear® DreamSeal®;

FIGS. 30-3 to 30-5 illustrate improvements and/or alternative arrangements of Puritan Bennett's Breeze® SleepGear® DreamSeal® mask according to embodiments of the present invention;

FIGS. 31-1 to 31-2 illustrate a known mask commercially sold by InnoMed Technologies under the name of Nasal-Aire™; and

FIGS. 31-3 to 31-4 illustrate improvements and/or alternative arrangements of InnoMed Technologies' Nasal-Aire™ mask according to embodiments of the present invention.

DETAILED DESCRIPTION OF ILLUSTRATED EMBODIMENTS

The following description is provided in relation to several embodiments which may share common characteristics and features. It is to be understood that one or more features of any one embodiment may be combinable with one or more features of the other embodiments. In addition, any single feature or combination of features in any of the embodiments may constitute additional embodiments.

While the patient interfaces below are described as including under-the-nose interface types, the patient interfaces may be adapted for use with other suitable interface types. That is, the interface type is merely exemplary, and aspects of the present invention may be adapted to include other interface types, e.g., nasal cushions, nasal prongs, full-face masks, mouth masks, etc.

Embodiments of the invention are directed towards moving from uncomfortable, unattractive mask systems to sleek and elegant patient interfaces that are soft, comfortable, lightweight, functional, therapy enhancing, fashionable, easy and intuitive to fit and adjust with little or no adjustment, shape holding, low impact, low profile, continuity of form, individualized or customized, and/or are more appealing and much less objectionable by patients and bed partners alike. The subject patient interfaces are less obstructive, less obtrusive, anatomically coherent and appear like an organic extension of and/or blends with the patient, rather than a bulky, mechanical extension affixed to the patient which can appear to be ungainly or unattractive. This can help the patient and the patient's bed partner more readily relax and/or sleep during treatment. Moreover, the patient interface can improve the overall perception such that the patient is simply wearing a garment like a night cap or bed clothes, etc. rather than being treated for a respiratory illness. This improved perception can help increase the chances that the patient will actually wear the patient interface and comply or better comply with therapy, therefore increasing the likelihood of effective therapy for the user of the device. There is also the possibility that the bed partner will more readily accept and participate in the patient's therapy by encouraging the use of a sleep-enhancing device that is easy to use/adjust, more attractive and/or appealing interface.

Patient Interface

FIGS. 1-1 to 1-16 illustrate a patient interface or mask system 10 according to an embodiment of the present invention. As illustrated, the patient interface 10 includes an interfacing structure 20 (also referred to as a cushioning structure or conforming structure) adapted to provide an effective interface with the patient's face and an air delivery and stabilizing system 30 (also referred to as conduit headgear or inlet conduit arrangement) adapted to deliver breathable gas to the interfacing structure 20 and support the patient interface 10 in a desired position on the patient's head. A cover (also referred to as a sock or covering) may be optionally provided to substantially enclose one or more portions of the interfacing structure 20 and/or the air delivery and stabilizing system 30.

1. Air Delivery and Stabilizing System

1.1 Background and Summary

Known patient interfaces typically include separate headgear and air delivery components that are used to locate and supply breathable gas to a mask or the like. Known headgear typically includes an assembly of elastic (or inelastic) straps, buckles, locks, and/or clips. Known air delivery components typically include 15-22 mm diameter spiral reinforced tubing and swivel connectors. These known arrangements of headgear and air delivery components can be difficult to use for those who are less dexterous and/or unfamiliar with them. These known arrangements of headgear and air delivery components can also be uncomfortable or impractical to lie on.

One aspect of the present invention relates to air delivery and interfacing structure stability provided by one combined system. In the illustrated embodiment, the air delivery and stabilizing system 30 includes four main components, i.e., tubing 40, a rigidizer 50, a back strap 60, and a manifold 70 (e.g., see FIG. 1-6). In use, a supply of air is directed to the manifold 70, e.g., located on or in front of the crown of the patient's head. The supply of air passes from the manifold 70 to the tubing 50, e.g., at least one and preferably two tubes, towards the patient's nose and/or mouth. The tubing 40 has the property of being collapsible to lie on, yet sufficiently rigid in other directions so as to maintain sufficient stability of the interface.

1.2 Tubing

In the illustrated embodiment, the tubing 40 includes two tubes or inlet conduits 42 (also referred to as gas passages or gas conduits) communicated with the interfacing structure 20 to deliver breathable gas to the interfacing structure 20 (e.g., see FIG. 1-6). In one embodiment, a single tube may be used. However, it is preferred that two tubes be used, so that a sufficient supply of breathable gas can still be delivered to the interfacing structure 20 when one of the tubes 42 is fully collapsed, e.g., due to the patient lying on his/her side. That is, when two tubes 42 are used, one or both of the tubes 42 may be open in use. In an alternative embodiment, more than two tubes may be used, e.g., three or more tubes. For example, the tubing may provide a four tube arrangement including two upper tubes along upper sides of the patient's face and two lower tubes along lower sides of the patient's face.

Each tube 42 includes a first end 42.1 adapted to engage a respective end of a frame 22 of the interfacing structure 20 and second end 42.2 adapted to engage a respective end of the manifold 70, as shown in FIGS. 2-1 and 2-2. In an embodiment, the frame 22 and manifold 70 may each include tube portions 25 adapted to engage respective ends of the tubes 42, e.g., via friction fit. In use, the tubes 42 are supplied with pressurized breathable gas from the manifold 70, and the pressurized breathable gas is delivered into opposing ends of the interfacing structure 20.

In the illustrated embodiment, the tube portions 25 of the frame 22 and manifold 70 (e.g., see FIGS. 2-1 and 2-2) each have a stepped configuration so that when the respective tube is attached thereto the joint has a smooth, almost seamless form, e.g., no visible step changes in the overall form. For example, the boundary between each tube portion 25 and the main body of the frame or manifold may have a step height substantially equal to the wall thickness of the respective end 42.1, 42.2 of the tube, and mating the tube portion and respective end of the tube will result in a smooth, almost seamless form at the joint. The smooth joint improves aesthetics and may have a functional benefit in reducing drag forces picked up on pillows, bedclothes, etc. as the patient rolls around in bed in use.

In an alternative embodiment, the two tubes may be independently connected to the supply of gas (e.g., positive airway pressure (PAP) device or flow generator). For example, as schematically shown in FIG. 2-3, one tube 42 may extend from one end of the interfacing structure 20 to a first outlet O1 of the PAP device and the other tube 42 may extend from the other end of the interfacing structure 20 to a second outlet O2 of the PAP device. In such an arrangement, the manifold may be eliminated or the manifold may be incorporated into the PAP device itself.

In another embodiment, the two tubes may be joined together at an outlet of the PAP device (e.g., both tubes adapted to be coupled to a single outlet of the PAP device), and then the tubes bifurcate (i.e., split or divide into separated tubes) towards the interfacing structure. For example, as shown in FIG. 2-4 a, tube 42(1) may be coupled to a single outlet O of the PAP device and then split into separate tubes 42(2) towards respective ends of the interfacing structure 20. As shown in FIG. 2-4 b, the tube 42(1) may include an internal dividing wall W to divide the tube into two conduits associated with a respective one of the tubes 42(2).

1.2.1 Collapsible and Thin

In the illustrated embodiment, each tube 42 is structured such that it may move between two phases, i.e., a first open phase in which the tube 42 allows the passage of air (e.g., see FIG. 3-1) and a second collapsed phase in which the tube 42 is fully collapsed and comfortable to lie on (e.g., see FIG. 3-2 b). Each tube 42 is structured such that the weight of any patient's head (e.g., adult or infant/child) resting on the tube 42 is sufficient to collapse the tube 42 so the patient may comfortably lie on his/her side (e.g., see FIGS. 1-3, 1-5, and 1-14). However, because the tubes have a consistency similar to that of a tubular balloon inflated under low pressure, each tube 42 may collapse under much less weight than a typical patient's head.

In the open phase, the tube is open or at least partially open so that the tube allows the passage of air, e.g., without undue resistance to flow, sufficient to provide treatment. In the collapsed phase, the tube is collapsed to substantially prevent the passage or conductance of air.

It should be appreciated that each tube need not collapse fully or entirely to provide improved comfort. For example, each tube may be structured such that it may move between a first open phase in which the tube 42 allows the passage of air and a second partially or substantially collapsed phase (e.g., see FIG. 3-2 a) in which the tube 42 is at least partially or substantially collapsed to restrict and/or at least partially prevent the passage of air.

In a partially or substantially collapsed phase, opposing inner walls of the tube may engage one another at one or more points or surfaces along their length such that conductance through the partially or substantially collapsed tube is minimized or even reduced to negligible amounts. Also, in the partially or substantially collapsed phase, the tube may be open enough to maintain a small degree of conductance of pressurized gas. A small degree of patency can be accomplished using wall thicknesses of a certain gauge (such that opposed walls will not contact or fully contact one another upon application of loads normally encountered during therapy) and/or one or more short anti-crush ribs provided to an inside surface of the tube.

Each tube 42 is sufficiently air tight and structured to deliver air from the top of the patient's head to the patient's nose without discomfort to the patient, e.g., see FIGS. 1-4 and 4-2. Impedance provided by the tube will be appropriate for the blower in use, regardless of whether one or both tubes are in the open phase. That is, the tube 42 provides a wide open cross-section with low impedance when in the open phase and provides a low profile when in the collapsed phase. Moreover, the tubes essentially provide a linear tubing system with a parallel line which can be switched on or off (i.e., open phase or collapsed phase), and the switching of either side of the parallel line off will have negligible effect on the total impedance of the tubing system. That is, the impedance “felt” by the PAP device is substantially independent of whether one or both tubes are open. The tubes may also be adapted to control pressure swings, e.g., deep breath by the patient.

In an embodiment, each tube 42 may have sufficient strength to maintain patency or an open, unblocked state without being pressurized. That is, the tube 42 may be structured such that it only collapses when it is “actively” compressed, otherwise the tube 42 remains in its open phase. In an alternative embodiment, the supply of gas may help to inflate each tube.

Each tube 42 may collapse anywhere along its length and may collapse to a substantially flat configuration so the tube 42 is substantially flat against the patient's face for comfort. However, the tube 42 may be structured to collapse along selected portions thereof, e.g., middle only, central only, etc.

In another embodiment, at least one tube may have at least one laterally ballooning feature. In such a tube (also referred to as a “bubble” tube), a portion of the tube is collapsed or partially collapsed and a portion of the tube is open, e.g., the tube is “pinched” in the middle to provide a general figure-8 shape. In another embodiment, at least one tube may have a relatively wide, flat shape to provide a stretched-out tube adapted to cover more of the patient's cheeks. For example, FIG. 3-5 a is a schematic view of a tube 142 in its initial configuration, FIG. 3-5 b illustrates the tube 142 when end portions 144, 146 are collapsed or partially collapsed into a flat configuration, and FIG. 3-5 c illustrates the tube 142 when a middle portion 145 is collapsed or partially collapsed into a flat configuration. In yet another variant, the tube could be preformed to have one or more relatively flatter portions 144, 145, 146 and one or more rounded conduit portions 147 as shown in FIGS. 3-5 b and 3-5 c.

It should be appreciated that the patient interface preferably does not collapse at the manifold and in an area at the front of the patient's nose, e.g., at the interfacing structure 20. That is, the manifold may be constructed of a substantially rigid material and the interfacing structure 20 may include a substantially rigid frame (e.g., frame 22 shown in FIG. 2-1) that prevents collapse in use. This arrangement ensures that an air flow path is provided from at least one of the tubes 42 to the patient's nose.

In an embodiment, each tube 42 may be molded from a silicone material, e.g., liquid silicone rubber (LSR), having a thin wall thickness of about 0.5 mm. However, each tube may have a wall thickness in the range of about 0.3 mm to 5 mm. The tubes may have varying colors, and the tubes may be formed in a mold with a polished surface to provide the tubes with smooth exterior surfaces. However, each tube may be constructed from other soft, flexible materials, e.g., thermoplastic elastomers (e.g., Santoprene), foam, foam laminate, closed cell impermeable foam, dipped and knitted textiles including cotton or silk. In an embodiment, each tube may be constructed from two sheets of material, e.g., laminate, that are attached to one another, e.g., heat welded, to form a tube. In an alternative embodiment, each tube may be constructed of a plurality of elements, e.g., relatively rigid elements, arranged in a concertina configuration so as to allow the tube to move between open and collapsed phases. In an embodiment, each tube may have a concertina configuration that allows each tube to collapse from one volume to another smaller volume. For example, FIG. 3-6 a illustrates a cross-section of a concertina-type tube 542 in a first phase that provides a first volume, and FIG. 3-6 b illustrates the concertina-type tube 542 in a second phase that provides a second volume smaller than the first volume. In this example, one side 543 of the tube 542 is placed adjacent the patient's face.

The tube arrangement according to an embodiment of the present invention contrasts with prior arrangements such as InnoMed's Nasal Aire and other forms of nasal cannula that are designed to resist crushing (i.e., breathable gas is able to be delivered through both tubes all the time) and thus present an uncomfortable structure for a patient to lie on. Furthermore, unlike prior arrangements, the tube arrangements according to embodiments of the present invention are capable of providing a sufficient supply of pressurized gas when one of the pair of tubes is fully collapsed. Because of the particular arrangement of the pair of tubes in accordance with an embodiment of the present invention, both tubes are not crushed at one time during normal use. This allows the patient to assume any sleeping position (e.g., total freedom of sleeping position) without compromising the supply of pressurized gas (e.g., see FIGS. 1-1, 1-3, 1-5, 1-7, 1-8, and 1-14). That is, the tube arrangement according to an embodiment of the present invention provides two or more tubes that cooperate to maintain sufficient conductance of gas (e.g., sufficient flow of gas at therapeutic pressure) and comfort to the patient without introducing unnecessarily high impedance. For example, when a two tube arrangement is provided, each tube has sufficiently low impedance (e.g., large enough hydraulic diameter) which facilitates the adequate supply of gas when one of the tubes is occluded, e.g., lain on.

1.2.2 Cross-Sectional Profile

In the illustrated embodiment, each tube 42 has a non-cylindrical cross-sectional shape which provides a blending contour to blend with the patient's face (e.g., see FIGS. 3-1 and 4-1 to 4-5). That is, each tube 42 provides a blending contour or free form with few or no sharp edges or straight lines. The blending contour is smooth, streamlined, sleek, and blends or tapers the tubes 42 with or into the contours of the patient's head, e.g., anatomically coherent, less obtrusive and more aesthetically appealing. In addition, the blending contour has no sharp edges that could cause discomfort, e.g., skin irritations or abrasions.

The contour or cross-section of each tube 42 may vary along its length, e.g., vary non-uniformly with location around the patient's head. In an embodiment, each tube may have a cross-sectional area that changes along its length with an approximately constant hydraulic diameter. For example, each tube 42 may provide flatter regions in certain areas, e.g., where the patient rests on the tube during sleep. In this way, the tubes can be said to be an organic extension of the patient's facial contours.

FIG. 3-1 illustrates an exemplary cross-section of a tube 42. As illustrated, the tube 42 has a generally D-shaped cross-section and includes an internal or inwardly facing surface 44 and an external or outwardly facing surface 45.

The internal surface 44 is relatively flat and adapted to sit substantially flush against the patient's face in use. The internal surface 44 may have a tapered configuration form an inner edge to an outer edge to provide a comfortable fit for a wide range of patients. The internal surface 44 provides a relatively large surface area which results in a more even load distribution. This arrangement is less likely to create pressure points in use. Also, the internal surface 44 may have grip-like material to help stabilize the patient interface on the patient's face. As described below, a rigidizing element may be provided to the internal surface to add rigidity to the tube.

The external surface 45 has a smooth contour that blends with the patient's face. That is, the external surface 45 has a profile or organic form with edges that blend into the patient's face, e.g., in a tangential manner, to prevent any edges from catching on bedclothes, pillows, etc., during sleep (e.g., when the patient rolls over).

As noted above, the generally D-shaped cross-section may vary along its length, e.g., tall, thin D-shaped cross-section near the patient's nose and wide, shallow D-shaped cross-section along cheek and near the top of the patient's head. For example, FIGS. 3-4 and 3-4 a to 3-4 f illustrate various cross-sections of a tube 42 along its length according to an embodiment of the present invention. Specifically, FIG. 3-4 a illustrates a cross-section of the tube 42 at the end adapted to engage the manifold 70, FIG. 3-4 b illustrates a cross-section of the tube 42 that is 20% of the tube length from the manifold end, FIG. 3-4 c illustrates a cross-section of the tube 42 that is 40% of the tube length from the manifold end, FIG. 3-4 d illustrates a cross-section of the tube 42 that is 60% of the tube length from the manifold end, FIG. 3-4 e illustrates a cross-section of the tube 42 that is 80% of the tube length from the manifold end, and FIG. 3-4 f illustrates a cross-section of the tube 42 at the end adapted to engage the interfacing structure 20. As illustrated, the D-shape of the cross-section varies along its length. Specifically, each cross-section has a width w and a height h, and the width and height of the various cross-sections varies along the length of the tube, e.g., a relatively long width and short height at the manifold end and a relatively short width and tall height at the interfacing structure end. Also, all of the cross-sections have a very similar or common hydraulic diameter, e.g., about 10-15 mm or about 13 mm. The shape may be configured based on aesthetic and/or impedance requirements. In addition, the shape may be configured to provide low profile, comfort, and/or stabilization.

However, the tubes 42 may have other suitable cross-sectional shapes, e.g., trapezoidal, semi-circular, cylindrical, oval, elliptical, flatter section, etc. Also, the tubes may have a flat configuration with anti-crush ribs. This arrangement is disclosed in U.S. patent Ser. No. 10/385,701, the entirety of which is incorporated herein by reference.

FIGS. 5-1 to 5-3 illustrate alternative cross-sections of the tube. FIG. 5-1 illustrates a tube 242 that more gradually blends into the patient's face. As shown in FIG. 5-2, the tube 342 may provide a gap 343 in the internal surface, e.g., to allow air flow or breathing. While less preferred than the cross-sections shown in FIGS. 3-1, 5-1, and 5-2, the cross-section of tube 442 in FIG. 5-3 would be more preferable than a normal cylindrical tube for its blending contour.

It is noted that a D-shaped or generally trapezoidal-shaped tube does not produce as pronounced pressure regions along bottom edges thereof as a semi-circular-shaped tube would. The reason for this is that the side walls of the D-shaped or generally trapezoidal-shaped tube meet the base at an acute angle α, i.e., less than 90°, as shown in FIG. 3-1. The side walls of the semi-circular-shaped tube meet the base at approximately 90°, and if the tube were pressed against the patient's face, the region where the side walls meet the base would be quite rigid and may lead to pressure points. In addition, a semi-circular-shaped tube may provide a discontinuity of form when viewed in relation to the patient's facial contours.

1.3 Air Delivery Rigidizing Element

In the illustrated embodiment, a rigidizing element or rigidizer 50 is provided to each tube 42 to add rigidity to the tube 42 (e.g., see FIGS. 1-6, 3-3, and 4-3 to 4-5). A rigidizing element 50 in accordance with an embodiment of the present invention is preferably thin and conforming when a patient lies upon it, yet has sufficient stiffness to resist out-of-plane bending. That is, the rigidizing element 50 is structured to allow bending in some planes and resist bending in other planes, e.g., allow bending towards and away from the patient's face. The rigidizing element 50 also makes the tube 42 inextensible or not stretchy so that the tube 42 is strong in tension and maintains its size.

In an embodiment, the rigidizing element 50 may provide structural integrity or self-holding form to the patient interface 10 so that the patient interface 10 can hold its shape and not fall into a heap, e.g., shape memory, whether the patient interface 10 is on or off the patient's head. The shape holding arrangement maintains the tubes in a desired position and may facilitate donning of the patient interface in use.

The rigidizing element 50 may be provided to an interior and/or exterior portion of the tube 42. For example, FIGS. 1-6 and 4-1 to 4-5 illustrate a rigidizing element 50 provided to an exterior portion of the tube 42 (e.g., along internal surface 44) that is adapted to engage the patient's head in use. As illustrated, the rigidizing element 50 may include tubular end portions 52 to facilitate connection of the tubes 42 to the manifold 70 and/or interfacing structure 20. The tube/rigidizer sub-assembly may also provide an extension 53 for supporting the back strap 60, e.g., see FIGS. 4-1, 4-2, and 4-4.

FIGS. 4-6 to 4-9 illustrate another embodiment of a rigidizing element 50 with the tubes 42 attached thereto. As illustrated, the rigidizing element 50 may be structured to extend under the interfacing structure, the manifold, and/or the back strap in use.

The rigidizing element 50 may have a varying thickness along its length, e.g., to vary the stiffness or rigidity of the tube 42 along its length. For example, the rigidizing element 50 may be thinner at the patient's cheeks and thicker at the top of the patient's head. In an embodiment, the rigidizing element 50 and/or tube 42 may be structured to accommodate a respective arm of patient eyeglasses.

In an embodiment, the rigidizing element 50 may be cut and/or formed from thin plastic sheet, e.g., 0.5 mm high impact polystyrene (or EPP foam). However, other suitable materials are possible, e.g., textile, nylon, polypropylene, high duro silicones, elastomers, etc., and the rigidizing element may have other suitable wall thicknesses, e.g., in the range of about 0.3 mm to 5 mm.

In an embodiment, each tubing/rigidizer sub-assembly may have a total thickness (e.g., thickness of collapsed tubing/rigidizer) of about 1.5 mm, e.g., 0.5 mm rigidizing element, 0.5 mm tube wall on one side, and 0.5 mm tube wall on opposite side. However, the total thickness may be more or less depending on application, e.g., 1-10 mm, 1-5 mm, less than 5 mm, about 10 mm, about 5 mm, and/or about 3 mm. It should be appreciated that the wall thickness of the tube and/or rigidizer may be adjusted for comfort and/or robustness, e.g., wall thicknesses thickened. The wall thickness of the tube and rigidizer is preferably as thin as possible, but may be thickened so as to be more shape-holding, self-supporting, and/or robust.

In an embodiment, a separate rigidizing element 50 may be employed. For example, see International Patent Application PCT/AU03/00458 (published as WO 03/090827), which is incorporated herein by reference in its entirety.

In an embodiment, a separate rigidizing element 50 may be formed, and then attached to the respective tube 42, e.g., by an adhesive or by a mechanical interlocking arrangement.

In another embodiment, the rigidizing element 50 may be co-molded or co-extruded with the respective tube 42. That is, the tube 42 and rigidizing element 50 may form an integral, one-piece structure.

In another embodiment, the rigidizing element may made of polypropylene and the tube may be made of a thermoplastic elastomer of a grade suitable for welding/co-molding to the polypropylene rigidizing element.

In an alternative embodiment, the rigidizing element may include multiple components that are adjustable or movable with respect to one another, e.g., slidable, to adjust the position and/or rigidity provided by the rigidizing element.

1.4 Back Strap

In the illustrated embodiment, a back strap 60 is provided to the tubing/rigidizer sub-assembly (e.g., see FIGS. 1-2, 1-6, and 6-1 to 6-4). The back strap 60 is adapted to be positioned generally on the patient's occipital bone in use to facilitate stabilizing the patient interface on the patient's head. The back strap 60 may also assist in providing an interfacing force against the interfacing surface, e.g., under the patient's nose.

In an embodiment, the back strap 60 (also referred to as an elasto-stabilizer or elastic stabilizer) includes a length of elastic strap 62. The two ends of the elastic strap 62 are attached to the tubing/rigidizer sub-assembly, e.g., via eyes 46 provided to respective tubes 42 as shown in FIGS. 6-3 and 6-4.

In use, the back strap 60 may sit in a range of positions on the patient's head and still effect an adequate interfacing force in both magnitude and direction. This arrangement allows some variation in fit size, and aids the patient's comfort in moving the back strap 60 to the most comfortable of locations, e.g., higher or lower positions at the back of the patient's head as shown in FIGS. 6-3 and 6-4. The elasticity of the back strap allows the patient interface to fit a broad range of the population, e.g., 80-90% of the population.

The back strap 60 is primarily used to maintain the patient interface on the patient's head, rather than provide an interfacing force. That is, the interfacing structure 20 does not require high tension for interface (as described below), and therefore the back strap 60 does not need to be relied on for tension for an interfacing force.

In an embodiment, the strap 62 may have selected elastic properties, e.g., from zero extension to a relatively small extension, the tension rises and plateaus. The tension may remain generally similar over a relatively large further extension until it reaches the fully extended elastic limit.

A range of alternative straps 62 may be provided with the patient interface for use with different size heads, e.g., different elasticity, thickness, length, etc.

The back strap 60 may have other suitable configurations with selectively adjustable lengths, e.g., baseball cap adjuster (e.g., see FIG. 10-4), hook and loop material, ladder lock, adjustable elastic. In an embodiment, as shown in FIG. 6-5, the back strap may include side rigid portions 65 (e.g., integrally formed with the rigidizing element 50) and an elastic strap 62 joining the free ends of the rigid portions 65.

In yet another alternative embodiment, the back strap may be constructed of the same material as the tubes, e.g., tube and back strap co-molded to a rigidizing element. In an embodiment, the two sides of the patient interface may be molded at once, e.g., two rigidizing elements held together by the back strap which blends into both rigidizing elements. To complete the patient interface, the tubes would be engaged with a manifold and an interfacing structure.

In an alternative embodiment, the back strap may be replaced by ear anchors adapted to engage the patient's ears and support the patient interface on the patient's face.

In another embodiment, the back strap may only extend across part of the occiput (e.g., the back strap comprises resilient fingers that extend inwards from each side and press against the occiput to provide a rearwardly directed force).

1.5 Manifold

The manifold 70 is provided to interconnect the two tubes 42 and direct air flowing from a suitable source, e.g., a blower, into the two tubes 42 (e.g., see FIGS. 1-2, 1-4, and 1-6). As best shown in FIG. 2-2, the manifold 70 is generally T-shaped and includes a base portion 72 and an inlet tube portion 74 that is coupled (e.g., movably coupled via a ball joint, hinge, general flexibility, etc.) to the base portion 72. In an embodiment, the manifold 70 is designed to be sleek and to have a form continuous with the shape of the patient's head and the patient interface, e.g., unobtrusive. For example, the manifold may have a relatively flat form or low profile to minimize the height or angle of air delivery.

The manifold provides a transition from the air delivery tubing leading from the PAP device to the inlet tubing leading to the interfacing structure. Thus, the manifold transitions non-crushable tubing of the air delivery tubing to crushable tubing of the inlet tubing. Also, the manifold transitions tubing profile, e.g., relatively round tubing of the air delivery tubing to relatively flat tubing of the inlet tubing.

The base portion 72 includes opposing tube portions 25 adapted to engage respective tubes 42, e.g., with a friction fit. The cross-sectional shape of the tube portions 25 may be non-circular and correspond to the cross-sectional shape of the tubes 42. The base portion 72 may be curved to match the shape of the patient's head and is otherwise suitably contoured such that it can rest and sit substantially flush with the top of the patient's head in use. However, the base portion may include other suitable connections or air holding bonds with the tubes.

The inlet tube portion 74 may be fixed to the base portion 72, or the inlet tube portion 74 may be movably coupled, e.g., swivel, to the base portion 72 so that the inlet tube portion 74 may be angled with respect to the base portion 72 in use. The swivel arrangement may provide 360° rotation or any other suitable angle range. The inlet tube portion 74 has an inlet tube 75, e.g., 15 mm diameter, adapted to connect to an air delivery tube T1 (e.g., see FIGS. 1-2, 1-7, and 2-2) connected to a suitable air delivery source, e.g., a blower.

In an embodiment, the manifold 70 and tubes 42 may be integrally formed as a one-piece structure, e.g., to reduce the number of parts.

In an embodiment, the manifold may be structured to control dynamic flow and/or reduce noise.

1.5.1 Location

The manifold 70 is positioned in a region on the top of the patient's head that does not interfere with a pillow when the patient interface is used (e.g., see FIGS. 1-2, 1-4, and 1-7). That is, the manifold 70 directs the air delivery tube T1 out of the bed so it does not interfere with the pillow and does not pass along the patient's body. In an embodiment, the manifold 70 may be positioned on the crown of the patient's head, e.g., generally in the plane of the patient's ears. For example, the manifold 70 may be positioned generally in the region of the Bregma in use.

An advantage of this approach is that tube drag does not directly affect the interface in use. For example, by placing the manifold 70 near the crown of the head, it is positioned furthest from the interfacing structure 20, so if the air delivery tube is yanked or moved, the movement has less affect on the interface, e.g., by changing the load distribution in the interfacing region, and therefore increases the stability of the interface. Also, the positioning of the manifold enables the tube connection to the mask to be less obtrusive by avoiding the patient's field of vision.

The manifold may provide multiple functions or utilities. For example, the manifold may provide a point of reference or anchor point for the patient interface. That is, the manifold may act as a head support or stabilizer, an air delivery conduit, and an inlet tubing attachment point. In addition, the manifold resists tube drag as described above.

1.5.2 Swiveling Features

In an embodiment, the manifold 70 is generally T-shaped and defines two generally perpendicular axes, i.e., the base portion 72 along a first axis and the inlet tube portion 74 along a second axis that is perpendicular to the first axis.

The manifold 70 may incorporate swiveling features that allow the manifold 70 to swivel or hinge about one or both axes (e.g., see FIG. 7-1). FIG. 7-2 illustrates a manifold 270 having a ball and socket arrangement that allows the inlet tube portion 274 to rotate or swivel with respect to the base portion 272. The base portion and/or inlet tube portion may incorporate one or more stops to limit swiveling in use. The swiveling feature allows the air delivery tube to be suitably angled with respect to the patient interface, e.g., so the air delivery tube does not extend into the wall or bed headboard.

1.5.3 Offset Attachment

In the illustrated embodiment, the manifold 70 is positioned at the top of the patient's head, e.g., see FIGS. 1-2, 1-4, and 1-7. In alternative embodiments, the manifold 70 may be offset from the top of the patient's head, e.g., positioned at a side of the patient's head. This offset arrangement may provide more comfort as there may be less drag (particularly if the patient sleeps on the opposite side of their head). This arrangement may also facilitate an alternative tube attachment and routing, e.g., a snorkel-like side tube routing.

The length of the tubes 42 may be selected to adjust the manifold 70 to a position where the patient can view and more easily manipulate air delivery tube connections.

In an embodiment, the manifold 70 may have an adjustable connection, e.g., sliding or translating coupling, so that two or more positions of the manifold (e.g., along a backstrap of the headgear) may be selected.

1.6 Location on Head

In the illustrated embodiment, the air delivery and stabilizing system 30 includes two alternative, complementary air delivery pathways located on different parts of the patient's head (e.g., preferably either side of the patient's face) so that a patient may roll through almost a complete circle without occluding both pathways.

In an embodiment, the air delivery and stabilizing system 30 has a generally oval or ring-shaped configuration (e.g., see FIGS. 8-1 to 8-4). In use, each tube 42 of the system has one end that passes generally over the crown of the patient's head and the other end passes under the patient's nose, as shown in FIG. 8-5. In this way, the air delivery and stabilizing system 30 is outside the patient's eyes and does not interfere with the patient's vision or field of view and may be simply donned as one does a cap. In an alternative embodiment, the ring-shaped configuration may incorporate a divider to split the ring shape, e.g., ring shape divided at manifold or under nose.

Each tube 42 of the air delivery and stabilizing system 30 passes along a respective side of the patient's face between the patient's eye and ear to provide an arrangement that does not obstruct the patient's vision. That is, each tube 42 is sufficiently spaced from the ear to reduce noise and sufficiently spaced from the eye so it does not affect the field of view. In an embodiment, the tube 42 passes in a direct line from the patient's nose to the crown of the patient's head. However, the tube 42 is not limited to any specific path.

For example, as shown in FIG. 8-6, each tube 42 may pass within a region defined between a first boundary curve P1 and a second boundary curve P2. The first and second boundary curves P1, P1 are represented by two identical curves, one curve rotated with respect to the other curve. The curves are positioned so that they are both on the extremes of the region. As illustrated, the first boundary curve P1 is adjacent to the eye at a position where it would impinge upon the patient's field of view, and the second boundary curve P2 is adjacent the patient's ear. The second boundary curve P2 may be described as a position adjacent a top forward location on the patient's auricle where the auricle joins the patient's temple. Dimension B shows a head height. As illustrated, curve P2 stops on the crown of the patient's head. That is, if the curve represented tubing, it would be substantially snug against the top of the patient's head. When the curve or tubing is rotated forward, dimension A shows the head height of a patient that this would fit. As illustrated, a fit range delta AB is achievable using the same non-adjustable tubing.

In an embodiment, the air delivery and stabilizing system 30 may pass along the upper jaw bone of the patient, e.g., avoid cheek and follow fleshy areas of the patient's face. Also, in an embodiment, the air delivery and stabilizing system 30 may reside over the mid-point of the patient's temple in use. However, the air delivery and stabilizing system 30 may be sufficiently soft so that sensitive areas do not need to be avoided for comfort.

It should be appreciated that positioning of the air delivery and stabilizing system 30 on the patient's head does not critically depend on exact alignment with certain facial features as do prior art systems. That is, a satisfactory interface may be formed and retained by the air delivery and stabilizing system 30 despite movement.

1.7 Other Aspects of System

1.7.1 Assembly

In a preferred embodiment, the patient interface 10 is structured such that little or no adjustment is needed to fit the patient interface to the patient's head. Thus, the patient interface is relatively self-locating, intuitive, auto-adjusting, easy fitting. In an embodiment, the patient interface may be assembled one handed, e.g., slip on like a hat.

As noted above, the air delivery and stabilizing system 30 has a generally oval or ring-shaped configuration, e.g., a generally truncated elliptical cone or funnel. A tapering surface or conical-elliptical ring may be provided between the inner and outer edges to define a contact surface that engages the patient. Depending on the size of the patient's head, the tapered contact surface will engage the patient's head in different positions. For example, if the patient has a larger head, patient interface may sit higher up on the patient's head. If the patient has a smaller head, the patient interface may sit more towards a rear portion of the patient's head. Once fit, the patient may adjust the back strap 60 as necessary. Thus, the patient may require a single adjustment to fit the patient interface to his/her head. Further details of such an arrangement are disclosed in U.S. Provisional Application No. 60/833,841, filed Jul. 28, 2006, which is incorporated herein by reference in its entirety.

In an embodiment, the oval or ring-shape configuration of the air delivery and stabilizing system 30 may be adjustable, e.g., depending on patient fit and/or preference. For example, as shown in FIG. 8-7 top and/or bottom portions of the “ring” may include an adjustment mechanism 55 to allow adjustment of the ring size, e.g., depending on patient's head size.

1.7.1.1 Method to Fit Patient

FIGS. 9-1 to 9-3 illustrate an exemplary method for fitting the patient interface to a patient. As shown in FIG. 9-1, the interfacing structure 20 may first be located under the patient's nose. Then, as shown in FIG. 9-2, the air delivery and stabilizing system 30 may be rotated about the interfacing structure 20 onto the patient's head. The patient interface is rotated, e.g., for X°, until the air delivery and stabilizing system 30 engages the patient's head and prevents further movement. Finally, as shown in FIG. 9-3, the back strap 60 may be adjusted as necessary to comfortably secure the patient interface on the patient's head.

In an alternative embodiment, the patient interface may be structured to provide “staged fitting” of the patient interface. In such embodiment, one part of the patient interface (e.g., air delivery and stabilizing system) may be engaged with the patient and another part of the patient interface (e.g., interfacing structure) may be subsequently engaged when the patient is ready for therapy to begin. This arrangement allows the air delivery and stabilizing system to be engaged with the patient's head, while the interfacing structure is out of engagement. For example, in the case of an Adam's circuit (e.g., such as that shown in FIGS. 30-1 to 30-4), the interfacing structure may be adapted to pivot upwards or laterally into a “standby” position that is out of the patient's field of view and/or not engaged with the patient's face or nose. The interfacing structure may be moved from the “standby” position to a fully operable/engaged position at the last minute just before the patient is ready for therapy (e.g., before sleep). In one example, the tube or the joint between the tube and the mask may be pivotable/bendable/movable to move the mask away from the face while still maintaining the headgear in place. For example, FIG. 30-3 illustrates an exemplary pivot 1915 at the joint between the tube and the mask that allows the mask to move away from the face (e.g., to a position shown in dashed lines).

1.7.1.2 Sizing

In the illustrated embodiment, the patient interface includes a single adjustment point. The adjustment mechanism may be either passive (e.g., elastic back strap) or require active adjustment (e.g., baseball cap fitting) to provide a one-size fits all arrangement. In an embodiment, the adjustment point may be tailored or modified to fit the patient at the point of sale, and then altered to prevent further adjustment, e.g., tear off.

In an alternative embodiment, the patient interface may have a non-adjustable slip-on shape, e.g., like a shoe, with little or no elasticity. In this arrangement, the patient interface may be provided in many different sizes, e.g., up to 20 different sizes, 5, 10, 15, or any other number of sizes (e.g., small, medium, and large). This arrangement may be aided by high mechanical compliance of the sealing interface to provide ample fit-range.

In another alternative embodiment, the patient interface may include a method for adjusting the size (e.g., length) of the headgear in either or both of the upper and rear sections of the headgear.

1.7.1.3 Surface Properties

In embodiments, the air delivery and stabilizing system may be textured, colored, foamed, and/or flocked (e.g., lots of little bits of yarn or fluff adhered to it) to give a fabric-like feel or softness for aesthetics and/or comfort. For example, the tubing, rigidizing elements, back strap, and/or manifold may be textured, colored, foamed, and/or flocked.

In an alternative embodiment, a sock S may be provided to substantially enclose one or more portions of the tubing, rigidizing elements, back strap, and/or manifold (e.g., see FIGS. 10-1 to 10-6). Such an arrangement is disclosed in U.S. Provisional Application No. 60/833,841, filed Jul. 28, 2006, which is incorporated herein by reference in its entirety.

In another embodiment, different materials may be co-molded in the same mold to provide a one-piece, integrated structure. For example, instead of providing a cover or sock to tubing, a fabric or cloth material may be co-molded with silicone tubing to provide a one-piece, integrated tube with a fabric/cloth exterior surface and a silicone interior surface. In such embodiment, the fabric/cloth material may be placed in a mold and then silicone may be injected into the same mold so that it bonds with the fabric/cloth material and forms a one-piece, integrated tube.

In another embodiment, multiple portions of the patient interface may be co-molded in the same mold with different materials to provide a one-piece, integrated structure. For example, a fabric/cloth material may be co-molded with tubing constructed of a first material, a manifold constructed of a second material, and a frame constructed of a third material to provide a one-piece, integrated structure. In an embodiment, the first, second, and third materials may include the same material with different durometers or hardnesses, e.g., tubing constructed of relatively soft silicone and manifold and frame constructed of relatively hard silicone. Alternatively, the first, second, and third materials may include different polymers or materials. Further, each portion of the patient interface may include regions with different properties, e.g., end portions of the tubing may be harder than an intermediate portion of the tubing. In such embodiment, the fabric/cloth material may be placed in a mold and then the first, second, and third materials may be injected into the same mold so that all the materials bond and form a one-piece, integrated structure, e.g., integrally formed tubing, manifold, frame with fabric/cloth cover.

In another embodiment, the tubing, rigidizing elements, manifold, and/or back strap may include silicone or other elastic beading for grip. This arrangement may be particularly useful for patient's with bald heads as the beading is adapted to grip the bald head and prevent sliding or movement of the patient interface with respect to the patient's head in use. In an embodiment, the patient interface may be reversible so that the beading may be selectively used, e.g., depending on whether the patient is bald. For example, fabric may be provided on one side and beading may be provided on the opposite side so that the patient may use one or the other depending on preference, e.g., beading oriented towards the patient's head for bald heads and fabric oriented towards the patient's head for hairy heads.

1.7.1.4 Manufacture

In an embodiment, each tube 42 may be manufactured as a bifurcated tube having a co-molded thickened section that forms a rigidizer.

In another embodiment, each tube 42 may be constructed of two pieces, i.e., a top half and a bottom half attached to the top half. In an exemplary embodiment, the top half may be constructed of textile or foam (e.g., with a sealing layer), and the bottom half may constitute a rigidizer with a skin-contacting portion.

1.7.2 Low Visual Obstruction

The patient interface may incorporate one or more regions having different colors (color contrast), patterns, and/or surface textures to reduce visual impact or distraction to the user. Such coloring, patterning, and/or surface texturing may be incorporated into the tubing, rigidizing elements, manifold, back strap, and/or interfacing structure. Alternatively, a sock having coloring, patterning, and/or surface texturing may be provided to the patient interface.

For example, FIGS. 10-1 to 10-10-6 illustrate a patient interface including a cover or sock S having a two-tone color scheme, e.g., a dark color D and a light color L. Such a patient interface is described in U.S. Provisional Application No. 60/833,841, filed Jul. 28, 2006, which is incorporated herein by reference in its entirety. As illustrated, the dark color D is positioned adjacent the field of vision. This arrangement provides a low impact, unobtrusive, sleek look that is less visually obtrusive to the patient and others.

Specifically, bright colors are more easily picked up by the patient and should be avoided in the field of view as they are more likely to cause a distraction than darker colors, e.g., bright colors reflect light into patient's eyes. Thus, the dark color D is positioned adjacent the field of vision to minimize visual obstruction or obtrusiveness. In an embodiment, the patient interface may only be visible to the patient at the very outer limits of their field of view, e.g., only the section of the patient interface which rests lower than the patient's eye level may be visible. Further, the dark color D may seem to disappear at the extremities of the field of view resulting in the patient undergoing very little visual obstruction.

Also, the two-tone textile cover S may slim the perception of the size of the patient interface on the patient's face. That is, this arrangement has the functional advantage that lighter colors, e.g., white, can be incorporated into the cover that make the relevant region look smaller, slimmer, or less bulky. Thus, the patient interface has a lower visual impact (e.g., less aesthetically obtrusive). In addition, the patient interface may be more fashionable like clothing. In alternative embodiments, one or more light colored lines, e.g., white lines, may be incorporated into the cover. Also, in an embodiment, the interface of the interfacing structure may include a darker color to reduce its visual obstruction.

It should be appreciated that different colors, patterns, and/or surface texture may be selected for different users. In an embodiment, the cover may be transparent or selected to blend in with the patient's skin, e.g., camouflaged or skin color. For example, if the patient has relatively darker skin, the cover could be black or dark brown to blend with the patient's skin. In an alternative embodiment, the color and/or texture of the cover may be selected to match the patient's hair.

1.7.3 Valve

In an embodiment, as shown in FIG. 11-1, a valve V, e.g., mechanical gate, may be provided to the patient interface that is adapted to open when both tubes 42 are occluded. For example, the valve V may remain closed if the interior pressure P_(int) is over 2 cmH₂O, and the valve may open if the interior pressure P_(int) is less than 2 cmH₂O thereby allowing the patient to breathe if both tubes 42 are occluded.

1.7.4 Connection to a Blower

In an embodiment, the patient interface 10 may be connected to the blower by a pair of air delivery tubes, i.e., a 15 mm tube and a 22 mm tube. As shown in FIG. 1-2, a 15 mm tube T1 connects the manifold 70 to a 22 mm tube T2, and the 22 mm tube T2 connects the 15 mm tube T1 to the blower. A quick-release connector 90 is provided at the transition between the 15 mm and 22 mm tubes T1, T2 to allow quick release of the 15 mm and 22 mm tubes T1, T2, and hence quick release of the patient interface 10 from the blower. In an alternative embodiment, a quick-release connector may be provided to the manifold 70 positioned adjacent the top of the patient's head. The quick-release connector may have any suitable structure to facilitate tubing assembly/disassembly, e.g., mechanical interlock, friction fit, screw-type arrangement, etc. The various connection points facilitates assembly/disassembly of the patient interface system which facilitates cleaning, adjustment, etc.

The 15 mm tube T1 has a suitable length to allow easy patient access to the quick-release connector 90, e.g., quick-release connector 90 in patient's field of view. Also, the 15 mm tube T1 has a suitable length so that the quick-release connector 90 may be positioned sufficiently away from the patient interface so the weight of the quick-release connector may be supported by the bed mattress or other support system.

Impedance in the system is as little as possible so that therapy does not vary significantly whether one or both tubes 42 are open. Therefore, the system is designed such that the hydraulic restriction or bottleneck is provided upstream of the patient interface including the case in which only one of the tubes 42 is open, i.e., the hydraulic bottleneck is provided in the manifold 70 or anywhere upstream of the manifold 70 (e.g., in the 15 mm tube and/or in the 22 mm tube).

Impedance is at least partially based on tube length. In the illustrated embodiment, the tubing is designed such that the tubes 42 are shorter than each of the 15 mm tube and the 22 mm tube, e.g., 15 mm and 22 mm tubes at least 40-50 cm long. In an embodiment, the 22 mm inlet tube may be about 2 m long and the 15 mm inlet tube may be about 70-75 cm long, with the bottleneck in the 22 mm inlet tube due to its length. However, other suitable lengths are possible.

In an embodiment, the air delivery tubing that leads to the manifold may have a look and feel similar to the inlet tubes 42. The air delivery tubing may have a smooth, noiseless outer portion, e.g., outer portion constructed of a material that is soft to the touch and provides sound insulation. The air delivery tubing may provide continuity of form from the PAP device or blower to the manifold of the patient interface.

1.7.5.1 Clip to Isolate Tube Drag

A clip or clamp may be provided to either air delivery tube T1, T2 and/or quick release connector 90 that is adapted to attach to a bed headboard or other support system. The clip or clamp supports the air delivery tube and/or quick release connector on the bed headboard or other support system to isolate tube drag from the patient interface. In an embodiment, the clip or clamp may be magnetic to allow magnetic attachment.

For example, FIG. 12-1 illustrates the quick release connector 90 magnetically attached to a headboard, FIG. 12-2 illustrates a clip 92 adapted to attach the tube T1 to a headboard, and FIG. 12-3 illustrates the tube T1 clipped to the patient interface.

1.7.5.2 Switch to Turn CPAP Therapy On/Off

A switch may be provided along any suitable portion of the patient interface that is adapted to turn the blower providing CPAP therapy on and/or off. For example, the switch may be provided on the air delivery tube or quick release connector. In an embodiment, the switch may be wirelessly communicated with the blower.

1.7.6 Inflatable Headgear

In an alternative embodiment, inflatable tubes may be provided around a relatively more rigid air delivery tube to insulate the air delivery tube from the patient's face.

1.7.7 Moveable Tubes

In an alternative embodiment, tubes may be provided that are adapted to move out of the way when the patient's head is turned.

2. Interfacing Structure

2.1 Background and Summary

Known patient interfaces typically include a silicone seal that is adapted to seal around and/or within the patient's nose and/or mouth. Sealing mechanisms may be categorized as: (1) a flap-type seal, (2) a bulk compression or gasket-type seal, or (3) a combination of (1) & (2). A flap-type seal may utilize the mechanics of a flexible membrane to achieve a reliably sealing interface. Compared to a flap-type seal that works by deflection of the flap, a bulk material seal works by compression of the material. A preferred interfacing structure of the present invention utilizes foam in the form of a bulk compression type seal although the foam may take other forms.

One aspect of the present invention relates to an interfacing structure 20 in the form of an under-the-nose interface 80 made of foam (e.g., see FIGS. 1-6, 1-8, 1-10, 13-1, 13-2) that provides an effective and superiorly comfortable engagement with the underside of the patient's nose in use. In embodiments, the under-the-nose interface may be in the form of a cupping portion, prongs, or pillows. The foam interface 80 may be supported by a support and/or frame or shell adapted to communicate with respective tubes 42 of the air delivery and stabilizing system 30 described above.

For example, as shown in FIGS. 1-6, 1-8, and 1-10, the foam interface 80 may be provided to a relatively stiff shell or frame 22, e.g., formed of silicone, including tube portions 25 adapted to engage respective ends of the tubes 42, e.g., via friction fit.

In another embodiment, as shown in FIGS. 13-1 to 13-2, the foam interface 80 may be provided to a cylindrical support or base 82, e.g., constructed of silicone, and the cylindrical support 82 is adapted to be attached to a relatively rigid frame (not shown) adapted to engage respective ends of the tubes 42. The cylindrical support 82 may have a substantially similar structure to the base portion of a nozzle assembly (with the nozzles removed) as disclosed in U.S. patent application Ser. No. 10/781,929, the entirety of which is incorporated herein by reference. The flexibility of the cylindrical support 82 adds compliance to the interface. The cylindrical support 82 may have a split base to be connected with a channel in the frame. In an embodiment, the interface, cylindrical support, and/or frame may be adapted to rotate to add further compliance and/or adjustment to the interface. In an embodiment, the rotational adjustment and positioning may be maintained through the use of friction, indexing, and locking mechanisms.

In the illustrated embodiment, the foam interface 80 is constructed of a very soft foam that is compliant enough to gently cradle the patient's nose and provide an unobtrusive and comfortable nasal interface, e.g., under-the-nose foam interface. The under-the-nose foam interface provides the visual freedom and unobtrusiveness of nasal prongs, without the intrusiveness and potential discomfort of silicone prongs inside the patient' nose.

One issue that has emerged with the prevalence of nasal prong interfaces is a recognizable decrease in breathing comfort where a cold, frictional or burning sensation may be felt inside the nose from air rushing through the nose, particularly upon inhalation and higher pressures when the air travels at higher speeds through the nose. This sensation has been dubbed the ‘jetting effect’. This jetting effect is thought to be partially due to the air entering the nose in a channeled manner through the narrow prong orifices and impinging on sensitive nasal mucosa. It may also be attributed to air temperature and humidity. Thus, another advantage of the under-the-nose foam interface is the elimination or minimization of the jetting effect that nasal prongs are known to produce. This is because the air is not being forced through narrow orifices inside the nostrils, but through a larger orifice that covers both nostril openings. The exit of the foam interface remaining entirely or predominantly outside of the nose allows for the impedance of the orifice to be matched to, or lower than, the nostril openings so that flow is not restricted and formed into a jet stream inside the nose. The foam also has a diffusing effect at the boundary of the flow as it enters the nose. The irregular surface of the foam may add turbulence to the boundary layer of the flow entering the nostrils and as such navigates the nostril cavity with less concentrated force on the sensitive anatomy inside the nose. This diffusing effect also allows for the alignment of the interface with the nostril to be less critical with respect to the generation of the jetting effect. The foam being slightly air permeable also has the advantage of minimizing the aspects of the jetting effect that are attributable to humidity and temperature. Cold air and temperature variable air entering and exiting the nose can cause an irritating sensation inside the nose with known interfaces. Upon exhalation, the foam may be infused with warm exhaled air, and upon subsequent inhalation this small amount of warm air may reenter and/or heat the air stream that enters the nose therefore reducing the jetting effect. Yet another advantage of the foam in relation to the jetting effect is its ability to retain moisture (e.g., moist air), again due to the permeable nature of the foam. Upon inhalation, the stored moisture may add to the humidity of the inhaled air and reduce the jetting effect.

In another embodiment, the under-the-nose interface may have a central portion that divides the singular orifice into two. In this embodiment, the two resulting orifices may be size-matched, smaller than, or larger than the nostrils.

In both of the aforementioned embodiments (single and double orifice), alignment of the orifices with the nostrils can be relaxed compared to nasal prong designs. This is a result of not having positively intruding features inside the nostrils. The interface allows for greater movement along the surface of the skin without compromising the interface and/or seal. As a result of the very low hardness of the foam (e.g., particularly the very soft viscoelastic grades), the foam may intrude slightly inside the nostrils as it takes the shape of the anatomy it is interfacing with.

In a preferred embodiment, the interface may be made from a very soft, viscoelastic polyurethane foam grade. One method of quantifying the viscoelastic nature of foam is to measure the rate of deformation or recovery of the foam after it has been compressed. In an embodiment, the rate of recovery is designed so that the interface remains comfortably and sealingly engaged with the user's face while wearing the mask. The viscoelastic nature has particular benefits for maintaining comfort and seal during movement while wearing the mask. In other embodiments, the range of viscoelasticity may range from a foam that has a very slow rate of recovery to a very fast rate of recovery.

Another aspect of an interfacing structure in accordance with a preferred embodiment of the present invention is its relatively slow rate of return compared to known interfacing structures. A silicone or other rigid elastomer cushion has a relatively fast rate of return in the order of 5 to 10 cm/sec or higher. In one embodiment of the invention, the interfacing structure has a rate of return of less than about 5 cm/sec. In a preferred embodiment, the rate of return is about 1 cm/sec.

Rate of return can be measured by sandwiching a sample of bulk material between a bottom flat, rigid plate and a top flat, rigid, light plate. The top plate is moved downwards by a predetermined distance, compressing the bulk material and then is released. The time it takes the bulk material to raise the top plate to the original position is measured. The measure will be relative only, because the time taken to return to the original position will be dependant on the weight of the plate. The rate of return is equal to the thickness of the foam divided by the time to return. A relatively fast rate of return will take place in under a second.

The preferred type of foam was measured using the above mentioned rate of return test and a very light top plate (of rigid foam) was used such that the weight of the top plate was negligible. The block of foam sandwiched between the two plates was 5 cm thick and was manually sandwiched down until it was about 1 cm thick. It took 3.5 sec to return. This corresponds to a rate of return of about 1 cm/sec. By comparison, a typical prior art silicone membrane would return in under half a second.

A related material property is hysteresis. With reference to FIG. 14-1, another aspect of a preferred embodiment of the invention is a material exhibiting hysteresis in the range of 25 to 35 percent.

It should be appreciated that the under-the-nose interface may be constructed of other materials that form a cellular polymeric structure, e.g., polyethylene, polypropylene, silicone, latex rubber.

It should also be appreciated that the under-the-nose interface may be constructed of other suitable material types and configurations, e.g., textile covered foam, textile, textile strata, silicone (e.g., dual wall silicone under-the-nose interface with membrane and undercushion), silicone foam.

In yet another embodiment, the foam interface features the foam acting as a HCH (Hygroscopic Condenser Humidifier) or HME (Heat and Moisture Exchanger). This allows heat and moisture to be captured and returned to the user's airway to increase breathing comfort as described above in relation to the jetting effect.

The porous moisture absorbing and moisture retaining properties of the foam allow for the addition of scented vaporous liquids to the interface before or during the wearing of the interface. Such scents may or may not be therapeutic in nature. The mechanical properties of the foam may be modified (e.g., pore size, surface tension) to adjust the rate of evaporation of the scented liquid. Similarly, the drying performance of the foam may be adjusted.

2.2 Bulk Material Properties

In the illustrated embodiment, the foam interface 80 is a very soft, flexible, visco-elastic foam (e.g., converted slabstock) that has a soft, comfortable feel against the patient's skin and a hardness or stiffness that resembles the soft fleshy anatomy of the patient's face with properties as defined in FIG. 14-1. If sufficient stability and sealing reaction force is afforded by the patient interface design, the hardness will ideally be softer than the fleshy anatomy of the face. The hardness of the interface being softer than the anatomy it is interfacing with maximizes comfort by allowing for minimal pressure to be applied to the face to achieve an interface or pressure increase to the user's airway (i.e., low hardness and high visco-elasticity allows low contact pressure and maximal conformance to the contours of the patient's face (shape forming ability)). The interfacing dynamics are also improved whereby the interface conforms around the facial anatomy more so than the interface deforming the face, e.g., interface can accommodate relatively small features on the patient's face (e.g., facial creases and features which are the size of dimples on a golf ball, undulations, etc.).

The foam interface provides a static seal that may allow lower strap tension from headgear to create a sealing force and a dynamic seal that allows the interface to withstand macro-movement from a patient rolling around in bed and maintain an interface. Such interface properties are described in greater detail below.

The visco-elastic foam has a much more natural feeling against the patient's skin compared to conventional silicone interfaces, which may have a sweaty, plastic feel. The foam may include a moisture content, e.g., slightly moist or damp after usage or washing, which may provide a cooling effect or a refreshing feel when air flows through the foam in use.

In a preferred embodiment, the foam interface 80 may be a low hardness, low to high density, soft, low odor, low air-permeability, low resiliency, low isocyanate index polyether polyurethane foam with a very fine heterogeneous cell structure and visco-elastic behavior. The foam also features color and colorfastness to a pantone reference. In addition, the foam may provide moisture wicking ability to wick moisture or sweat from the patient's skin. In an embodiment, properties of the foam interface may vary along its thickness, e.g., density, porosity, or hardness of the foam may vary in different layers, and/or properties of the foam interface may vary along its perimeter, e.g., breathability may vary in different regions of the interface's perimeter. Visco-elasticity is the range of recovery of the foam interface from compression.

For example, FIGS. 13-3 to 13-4 illustrate foam with a mixed heterogeneous cell structure and FIGS. 13-7 a and 13-7 b illustrate foam with a layered heterogeneous cell structure. FIGS. 13-7 a and 13-7 b also illustrate how properties of foam may vary in different layers. As shown in FIGS. 13-7 a and 13-7 b, the foam may include three layers, i.e., small, medium, and large cell layers. In FIG. 13-7 a, small cell layers are near the surface and the cell layers get gradually larger towards the interior, and in FIG. 13-7 b, large cell layers are near the surface and the cell layers get gradually smaller towards the interior. However, the layers may have any suitable arrangement, e.g., medium layer near surface, then small and large layers towards interior. Such cell structure arrangements may be achieved depending on the choice of manufacturing methods.

FIG. 13-7 c illustrates a foam including a reinforcement element R, e.g., constructed of a laminate of stiffer foam, plastic, or metal, at an interior portion thereof. The reinforcement element R is structured to add rigidity to the foam in use. The foam portions on each side of the reinforcement element may include a homogeneous structure (as shown in FIG. 13-7 c) and/or a heterogeneous structure (layered or mixed). In a preferred embodiment, the reinforcement element R may be situated on one side of the foam interface, e.g., the bottom/non-facial contacting surface. In this way, the reinforcement may provide dual functionality, i.e., providing both reinforcement and a method for attachment to the mask (e.g., mechanical interference fit, Velcro, pressure-sensitive adhesive).

FIG. 14-1 illustrates a table of mechanical properties of a foam interface according to an embodiment of the present invention.

One aspect of a preferred embodiment of the present invention is the low hardness of the foam (or other soft material) of the sealing structure. Hardness can be defined in terms of both indentation and compression hardness. A preferred indentation hardness is in the range of 25 to 80 N at 40% while a preferred compression hardness is in the range of 0.4 to 1.5 kPa.

The foam interface according to an embodiment of the present invention may also include a degree of one or more of the following characteristics:

Cellular foam type—flexible polyurethane;

Polyurethane type—polyether based;

Cell structure—control of the cell structure of the foam is desirable to control the feel (also known as the “hand”) and look of the foam. The cell structure may be controlled to have a more heterogeneous or more homogeneous distribution of cell sizes, and this can affect the feel and look of the foam in various ways. The foam can also be produced to have a cell structure with varying degrees of open and closed cell content, which can affect several aspects of the foam's properties, e.g., air and moisture permeability.

Sealing—foam with a high closed cell content may have sufficiently low permeability so that a positive pressure seal may be created inside the interface upon compression against the skin. In an embodiment, the foam may include significantly more closed cells than open cells, e.g., 90% closed and 10% open. The compressive force provided by the foam to seal is therefore a function of the mechanical stiffness of the foam, and also the compressive stiffness added by having pressurized air inside the foam's cellular structure (e.g., air spring/air pressure stiffness). In this manner, the sealing function is provided while still allowing a small deliberate flow of air to escape along the surface and through the body of the foam structure. In embodiments, the foam has a cut, open cellular structure against the skin, however other embodiments may include foam that has a permeable skin. Another embodiment may have foam that is skinned (both permeable and impermeable skin) only on the skin contacting surfaces of the interface, leaving flow to pass through the body of the foam structure rather than along the skin-contacting surface.

Air permeability—the foam can be produced to have a controlled range of air permeability. Typically, for a sealing application, foam would be produced to have the highest closed cell content possible to prevent air or moisture from passing through the foam. In an embodiment, it may be desirable that there is allowed a relatively small amount of air permeability. This has several distinct advantages in relation to both the comfort and sealing performance of the interface when it is worn, e.g., allowing a small, diffuse flow to pass through the foam gives the skin in contact with the interface the ability to breathe, and for excess moisture to be removed from the interface during use;

Air permeability durability—maintenance of the desired level of air permeability throughout the component usage life is desirable because the flow through all elements of the mask system may be required to meet a given specification. Changes in air permeability can occur with cyclic mechanical compression loading therefore measures that are taken to improve the durability of the foam structure in relation to its permeability are an advantage. In a preferred embodiment, a polyurethane formulation that uses an MDI (Methylene-Bis-Di-Isocyanate) type isocyanate may be chosen to give the foam a durable closed cell content;

Odor/Volatiles—As the foam is intended to be used in close proximity to a person's nose, any measure that can be taken to minimize or preferentially modify the odor is an advantage. In a preferred embodiment, a polyurethane formulation that uses an MDI (Methylene-Bis-Di-Isocyanate) type isocyanate is a preferred choice to minimize odor;

Particulates—The chemistry and processing of the foam is chosen such that the foam component will not produce small particles that may be inhaled during use;

Feel/Hand—There are aesthetic advantages to producing the foam to have a feel that is silky and soft. In a preferred embodiment, the foam is produced to have a fine cell heterogeneous cell structure to maximize the smooth feel of the foam, and this can also aid in minimizing the potential for skin abrasion and irritation. Another aspect of the foam's mechanical properties that may aid its aesthetic appeal is for it to be produced with a high level of visco-elasticity, which gives the foam an intriguing interactive property;

Durability—The foam chemistry may be chosen so that it maintains its desired mechanical properties for the required shelf life and usage life of the component (e.g., foam structure may be manipulated to have predetermined life span, ranging from single use to long term use). This affords the advantage of providing a renewable product to the user on suitable replacement frequencies whereby the foam component may be replaced on a daily, weekly, monthly or other basis. Components that are packaged in predetermined multiples may then be supplied to the user, e.g., on a 3, 6, or 12 monthly or other suitable basis;

Thermal stability—the foam may be designed to withstand the thermal conditions of storage and transportation. It may also be designed to withstand the temperatures of disinfection and sterilization processes (e.g., autoclaving temperatures and potentially temperatures up to 180 degrees);

UV stability/Light fastness—the foam material will not breakdown easily with light exposure;

Swelling resistance—the foam component may be designed to have given swelling characteristics when saturated with water or other liquids. It may be designed to minimize or maximize its change in geometry depending on the desired characteristics of the foam under saturated conditions (e.g., swelling may be desirable to open the pores of the foam for cleaning, swelling may be undesirable to preserve the functional geometry under saturated conditions);

Dryability—the foam component may be designed to become dry under specific time constraints and environmental conditions, e.g., the component may be moist after usage or cleaning procedures so it may be desirable for the component to dry as quickly as possible prior to further usage, e.g., moisture in the interface may be desirable under certain usage conditions (cool feeling against the skin in hot conditions), so it may be advantageous for the component to retain moisture for longer periods of time, e.g., the component may be designed to dry during use by the air flowing through the material under the pressurized conditions during CPAP therapy (self drying);

Hydrolytic stability—the chemical formulation of the polyurethane foam may be chosen to give the foam a desired level of hydrolytic stability. The choice of a polyether type polyol over a polyester type polyol may give the foam improved resistance to hydrolysis (mechanical breakdown in the presence of moisture);

Color—the foam component may be colored to a defined Pantone reference (e.g. PC287);

Color fastness—A key challenge with respect to the use of foams is discoloration, both from natural aging and environmental factors during use. This is particularly an issue with natural and light colored foams. One method of countering discoloration is to deliberately color the foam with colors that change less obviously with age and usage (e.g., darker and more intense colors may discolor less). That is to say that the coloring of the foam has a functional attribute in preserving the perceived utility and cleanliness of the component during its usage life. Another issue that may occur is the running of any dye or pigment that is removably included in the foam structure. In a preferred embodiment, a reactive colorant is incorporated so that color reacts into the foam chemical structure so that it becomes part of the polyurethane chemical background, e.g., Reactint™ Colorants from Milliken Chemical. This gives the foam a significant advantage in its intended application to resist discoloration such that the product presents well upon initial usage and remains presentable with ongoing use;

Slabstock packaging—slabstock foam may be wrapped and sealed in plastic for shipment and storage;

Component packaging and distribution methods—The foam interface components may be designed to have a predetermined usage life. In this case, the component may need to be replaced on a more frequent basis than that which is currently known in the industry. For convenience of replacement, the component may be packaged to include multiple components in one package (e.g., box or carton). For example, one box or carton of components may include 50 components, 100 components, monthly supply of components, yearly supply of components, or other suitable basis. Components may be individually packaged and manufactured as part of a continuous perforated strip and provided in one package (e.g., single foam interface in one package similar to a condom wrapper having two side walls sealed about their perimeter). The components may be in grouped or solitary component cells. In an embodiment, a significant advantage is afforded by vacuum packaging the components. This form of packaging offers protection against aging from environmental factors (e.g., oxygen, humidity), as well as the ability to provide the component in a customized micro-environment (e.g., inert gases to prevent aging, scented gases for therapeutic and non-therapeutic purposes, color, flavor). Vacuum packaging also offers a significant advantage in reducing the physical volume of the product for shipping efficiency and logistical convenience. The foam can be compressed for extended periods of time—weeks or months—and still return to its uncompressed shape when the package is opened. FIG. 14-3 is a schematic view of a rotatable dispenser or reel D adapted to dispense individual packages P containing a foam interface, e.g., continuous stream of individual packages separated by perforations to allow perforated tear-off. However, the components may be separated by other suitable frangible or breakable connections.

Machinability—foam may be produced to be sufficiently dense and hard so that it can be machined into intricate 3D geometries;

Biocompatibility—Biological safety (biocompatibility) is paramount in the main intended applications for the foam. It must therefore not emit any harmful volatiles or have any harmful or irritating interactions with the human body. The chemistry and processing of foam is chosen to produce a foam that is in compliance with ISO 10993 biocompatibility standards;

Microbial growth—The foam structure may provide an environment that houses potential microbial (e.g., bacterial, fungal) growth, particularly in the presence of warmth and humidity and in close proximity to the nose. Any measures that can be inhibitory to the growth of fungus and bacteria may be desirable to preserve the cleanliness and/or prolong the usage life of the component. Typically, this is achieved by using non-porous materials or skinned porous materials that are minimally absorbent and easily cleanable for components that are in intimate contact with the user. However, due to the significant advantages for comfort and sealing performance in using a revealed, cut or open cellular structure (e.g., cut foam) against the face (as outlined in this disclosure), other methods must be pursued to address cleanliness and longevity of the component. In embodiments, the foam interface component is configured to be replaced at suitable frequencies (e.g., daily, weekly, monthly or other suitable regime). Suitable cleaning and maintenance regimes may also be recommended for the component (e.g., washing, drying, cleaning solutions (e.g., isopropyl alcohol), steaming, microwave sterilization). Another method to inhibit microbial growth is to include an antibacterial or antimicrobial agent (e.g., AEGIS brand antimicrobial for polyurethane foams) into the foam chemistry; and

Recyclable/Biodegradable—As the foam interface may be a frequently replaced component, the foam grade may be selected to be degradable within a chosen timeframe for minimal environmental impact. This may be expressed as a half life for the material to break down in landfill. In an embodiment, the foam is designed to break down in a time frame that is much less than materials known in the industry (e.g., silicone, skinned porous structures, gels). This may be achieved by augmenting the chemistry of the foam and porous structure of the foam to allow the ingress of landfill and microorganisms that aid the breakdown of the foam. Another significant advantage of the foam that minimizes environmental impact is that the material is much softer and of much lower densities than typical materials known in the industry, meaning that the material may be easily compressed and take up far less space in landfill.

As noted above, the foam interface components may be available individually and/or in box sets or cartons. This arrangement provides the possibility of a broad range of distribution channels, e.g., available via home-healthcare dealer, chemist, internet, etc.

In an embodiment, when the interface component wears out or needs replacement, the patient may order a box when needed or a replacement box (e.g., including daily-use interface components) may be periodically sent out to a patient, e.g., patient signs up for 1 year supply with monthly delivery.

This arrangement provides repeat business for a home-healthcare dealer. Also, this arrangement creates assembly line efficiencies because an assembly step (i.e., attachment of interface component to frame) is transferred to the patient. This arrangement may be adapted to reduce shipping by setting up manufacturing locally. In addition, this arrangement may provide an advantage to sleep labs because they do not need to sterilize, but just use disposable interface components.

In an embodiment, the packaging of the component may reflect replacement or reordering requirements. For example, the last items in a box may be packaged differently to indicate “end of supply”. In another example, the packaging may include different colors to indicate different days, weeks, months, etc.

As noted above, the foam structure may have a certain usage life or life span. According to an embodiment of the present invention, the foam structure may include an end-of-life indicator to indicate that this usage life has been reached.

For example, the end-of-life indicator may include one or more of the following: pH based color change (microbes produce acid to cause color change at replacement frequency); dirt/color changes; environmental aging (take environmental gases out of packaging); adhesive deteriorates with time (provides single assembly so patient cannot remove component without destroying it—cohesive strength of glue greater than adhesive); and/or packaging include color guides that you match the component to see whether it needs replacement.

2.3 Surface Properties

The foam interface 80 may be manufactured (e.g., from free rise slab stock) to have a skinned surface or a cut, unskinned surface. Because foam has a cellular internal structure, when the foam is cut (e.g., die cut), an open cellular structure is exposed. The cut, open cellular structure on the surface of the interface in contact with the skin has different performance characteristics compared to a skinned foam, particularly when used as a patient interface. For example, FIGS. 13-3 and 13-4 illustrate a foam interface 80 having a cut, unskinned surface CS, and FIGS. 13-5 and 13-6 illustrates a foam interface 80 having a skinned surface SS. As illustrated, the cut surface CS in FIGS. 13-3 and 13-4 exposes the cellular structure of the foam, e.g., air bubbles and pin holes exposed. In contrast, the skinned surface SS in FIGS. 13-5 and 13-6 conceals the cellular structure of the foam, e.g., smooth exterior surface with no air bubbles or pin-holes exposed.

2.3.1 Comfort

Specifically, a foam including a cut cellular structure (e.g., see FIGS. 13-3 and 13-4) on surfaces that interface or contact with the patient's skin has a different feel against the skin particularly compared to silicone material, which is used almost without exception in the industry. Also, the foam may be designed to have a very pleasing, comfortable tactile property that is not sticky or plastic in feel as with silicone. A relationship exists between the cellular structure of the foam and its comfort against the patient's skin. Foam can be produced to have a coarse to very fine-celled structure, and a homogeneous or heterogeneous distribution of cell sizes. These properties may be controlled through the manufacturing process. In a preferred embodiment, to maximize comfort against the patient's skin, a heterogeneous cell structure with a high content of fine sized cells may be preferred.

2.3.2 Sealing and/or Gripping Function

The cut cellular surface (e.g., see FIGS. 13-3 and 13-4) of the foam provides seal and/or grip. The foam may mechanically deform and engage the patient's face, e.g., to provide seal, and may also grip the skin sufficiently so as to not dislodge (e.g., and lose seal) under micro-movement (i.e., less than 1 mm). A cut cellular surface provides this grip (e.g., friction grip) and may be improved in combination with a “wetter” feeling foam grade and a high degree of softness and visco-elasticity in the foam grade. If the seal and/or grip is dislodged, it should regain its sealing and/or gripping properties easily, ideally without the need to reseat the patient interface on the patient's face. An example of a preferred foam may be a very soft, low (isocyanate) index foam having a wet, sticky, and/or moist feeling to touch. The “stickiness” or “wetness” of the foam may allow sliding movement of the foam along the patient's face without substantially breaking the seal, e.g., “crawling” seal. That is, the location of the seal may be shifted without losing contact with the patient's face and without losing substantial therapeutic pressure. The degree of grip or stickiness may be determined at least in part by surface tension (e.g., coefficient of static friction) and/or the geometry of the cut surface (e.g., roughness).

2.4 Geometry

The foam interface 80 may have a geometry that is generally cradle shaped (i.e., curvature in one direction) or saddle shaped (i.e., curvature in two directions). The interface may also have more than two directions of curvature and complex curvature arrangements to address, match, or deliberately mismatch certain anatomical regions, depending on the intended function of the geometry.

In the illustrated embodiment, the top surface of the foam interface 80 provides a saddle shape that includes curvature in two directions that aids engagement of the patient's nose and its orifices. For example, curvature in a first direction (e.g., see front view of FIG. 15-1) is structured to accommodate the anatomy that forms the alar angle of the patient's nose, and curvature in a second direction (e.g., see side view of FIG. 15-2) is structured to accommodate the anatomy that forms the naso-labial angle of the patient's nose. The degree of curvature in both first and second directions may be traded for extra compliance in the interface mechanical properties in combination with extra interface thickness (pile), e.g., the first and second curvature directions may be omitted for an interface that has sufficient softness and thickness to comfortably and effectively hug engage and seal against the interfacing (e.g., nasal and facial) anatomy.

In an alternative embodiment, the mechanical properties of the foam may be adjusted (e.g., softer) so that the interface will seal effectively using a geometry that has a flat top surface (without curvature in the first and second directions described above).

In another embodiment, the curvature and shape of the foam may be provided by the frame, backing, or other support structure that the foam is attached to.

Most sealing interfaces known in the art (especially silicone interfaces) are membranous. They are long, thin and flexible. The cross section of the membrane has a high aspect ratio (length divided by width or thickness) and hence, in combination with the softness of the membrane's material, it buckles easily along its length and bends easily across its width. Membranes typically do not compress along their length because they buckle easily and cannot support a compressive load in the direction of its length (the material buckles before it compresses). This ability to buckle and bend gives a membrane type seal its ability to conform and adapt to the varying anatomy of the face, particularly when presented (typically) tangentially to the face. Air pressure inside the mask is known to provide a supporting reaction force to the membrane against the face.

The under-the-nose interface according to an aspect of the present invention is not a membrane and does not behave as such. Its cross sectional shape has a low aspect ratio and may be approximately square, rhomboid, rectangular or diamond in shape, as illustrated in FIGS. 15-1 to 15-2. In other embodiments, the cross-section may be round, elliptical, or other more organic shapes depending on the possibilities afforded by the manufacturing process. Because the interface cross-section is not long and thin, it does not behave as a membrane, but as a compression seal. So rather than relying primarily upon its ability to buckle to conform (tangentially) to the face like conventional membrane seals, it relies upon its softness and compliance in a direction normal to the face to conform to the facial anatomy that it is interfacing with. The subject interface is also not as reliant upon air pressure to support the interfacing structure and/or form a seal. The substantial thickness of the cross section in combination with its circular or annular profile means that it is predominantly self-supporting, and as described previously the compressive force is incrementally a function of the pressurized air (air spring stiffness) where the foam sealing structure is air-permeable. The interface may deform outwardly by the positive air pressure inside the mask chamber, but this deformation is a feature that may encourage the interface to engage the anatomy that it is interfacing with, e.g., the shape of the interface may change under pressure to more closely approximate the shape of the patient's face.

2.5 Thickness

In an embodiment, the foam may have a thickness of about 5-20 mm, e.g., 15 mm, depending on the hardness and visco-elasticity of the foam, so that the foam can deform with a hugging or wrapping effect under and around the bottom of the patient's nose. In other embodiments, depending on the number of layers of foam that make up the sealing interface and the mechanical properties (e.g., hardness) of each layer, the thicknesses may vary accordingly, e.g., 5-50 mm, 10-30 mm, 14-20 mm. For example, the thickness of the skin-contacting layer of foam may be very soft and very thin (e.g., 1-3 mm), and the conforming layer harder and thicker (5-20 mm). A harder and similarly thin or thinner (e.g., <1 mm) layer of foam may serve as a layer acting as an attachment mechanism.

The thickness of the foam may determine the mechanical compliance of the interface in combination with the hardness of the foam. A softer foam in combination with a greater thickness can provide additional mechanical compliance and fit range, specifically when compared to silicone seals known in the art. The density, hardness, and thickness of the foam can be controlled to achieve an interface that delivers a therapeutic pressure and a comfortable fit without fully compressing the provided foam thickness. Due to the forgiving and compliant nature of the foam, a distinct advantage over other interfaces known in the art is that of sizing consolidation, and even the possibility of providing a one-size-fits-all interface. That is, the softness and compliance of the material used in the interface may allow the interface component to fit a much broader percentage of the population with the same or a reduced number of sizes.

2.6 Orifice

In a preferred embodiment, the foam interface 80 includes a single orifice 84 adapted to interface with both of the patient's nostrils (e.g., see FIGS. 13-1 to 13-2). Specifically, the interface compresses around the openings of both left and right nostrils, e.g., either surrounding or partially occluding the nostrils, such that the orifice 84 is in airpath communication with the nasal airways. In alternative embodiments, the airpath communication may be via two or more orifices. In embodiments, the profile of the orifice 84 may have a generally round, rectangular, rounded rectangular, triangular, elliptical, or oval shape. However, other suitable orifice shapes are possible, e.g., rounded triangular shape, rounded trapezoidal shape, rhomboid shape. In a preferred embodiment, the orifice matches the shape of the external profile of the component, however the orifice profile and external profile may differ in shape considerably (e.g., the external profile may be elliptical and the internal profile may be triangular). In an alternative embodiment, the foam interface may include a block of foam with no orifice and the permeability of the foam adjacent the airway openings may be sufficiently high so as to allow sufficient airflow to the patient's nose.

2.7 Interfacing Path

In the illustrated embodiment, an external upper perimeter of the foam interface 80 forms an interfacing path P (e.g., see FIGS. 13-1 to 13-2) that encompasses the inferior width of the nose, e.g., interfaces outside of nose or external nares.

For example, the foam interface may be designed to engage the underside of the nose. The geometry of the interface may be described generically as annular, having an inner and outer perimeter when observed in top view. The inner perimeter of the interface (which defines the orifice) may encompass the nostrils or partially occlude the nostrils making alignment of the interface with the nostrils less critical. The area between the inner and outer perimeter may engage a broader area of the face in comparison to other interfaces known in the art (e.g., nasal prongs) to provide a more evenly distributed pressure and low force on the face. The outer perimeter may sit within the inferior outline of the nose or give a close geometrical match to the width of the nose itself. In a preferred embodiment, the outer perimeter lies outside of the inferior outline of the nose to enhance the stability and snugness of fit by allowing the interface to have a wrapping or cradling effect around the width of the nose. This can aid the unobtrusive visual perception of the product when viewed from other than a first person perspective. Alternatively, the outer perimeter of the interface can be designed to lie outside the inferior outline of the nose, having a hugging or wrapping effect around the width of the nose. In the case where the outer perimeter of the interface is wider than the nose, this arrangement may provide enhanced stability and snugness of the interface. It may also allow for increased intuitiveness of fitting the interface, especially in combination with a first direction curvature or V-shape (looking front-on at the face). The interface then features a self-alignment mechanism and intuitive location for the nose to be snuggly received.

In an embodiment, the foam interface is structured to sit under the nostrils and the angle of the interface or interfacing vector is more diagonally upward towards the crown of the head as opposed to directly backwards and into the plane of the face, as is typical of the conventional over-the-nose interfaces.

For example, as shown in FIG. 16-1, the patient interface may include a first loop LP1 (e.g., air delivery tubes) and a second loop LP2 (e.g., back strap) connected to the first loop LP1 in use. As illustrated, the first loop LP1 passes along an underside of the patient's nose, along the cheek region, above the ears, and over the crown of the patient's head to define a sealing force against the underside of the patient's nose. The second loop LP2 passes generally over the occipital bone to define a headgear vector at an angle α between 40°-80° (e.g., 60°) with the first loop LP1.

Another embodiment is shown in FIGS. 16-2 to 16-3 which schematically illustrate a frame 222 for supporting the foam interface that is adapted to angle the interfacing vector more backwards. In combination with tubing having a rigidizing element, this allows the separation of sealing forces and forces that stabilize the patient interface on the head. More distinct control and adjustment of these forces is therefore provided as more of the stabilizing forces are supported above the top lip and on the cheek region of the patient. Thus, the interfacing vector is less forcibly directed into the patient's nose, improving the comfort for the patient. In another embodiment, the stabilizing forces may be relieved off the top lip and born more on the cheek region by providing load-bearing features on the headgear adjacent to the interface. This provides greater stability of the mask system on the head without the need to pull the very soft interface too tightly into the nose. The load bearing features may form an integral part of the foam interface component and extend along the (e.g., inner) facial contacting surfaces of the headgear. They may also be permanently or removably fixed to the headgear separate to the interface.

Further, the surface area provided by the frame may be smaller (e.g., narrower width across the face, narrower diameter), which may provide a smaller reaction force into the patient's face to achieve an effective interface.

2.8 Breathability

According to an embodiment of the present invention, the foam interface may include a breathable or permeable foam (e.g., based on a cut surface and/or the elimination of skin) that allows a deliberate amount of airflow both through the interface material (e.g., foam bulk structure) and between the interface and the patient's skin (e.g., cut surface of foam). Patient comfort and compliance is enhanced by decreasing the accumulation of sweat around the face, keeping the skin drier, and moderating the temperature of the skin in contact with and around the interface. Ideally, the airflow is designed to be less than an amount that causes excessive drying of the skin and cooling of the anatomy around the interface when worn on the face.

That is, the foam's construction provides a breathable interface such that condensation buildup and associated irritation can be avoided at the contact interface between the patient and interface. The foam provides “a leaky” interface (e.g., measured by a percentage of vent flow) with intentional/controllable leak through the foam structure/matrix that helps to create air circulation to keep the contact surfaces relatively dry and comfortable (e.g., about 10% of vent flow, 30-40% of vent flow). The amount of leak provided by the foam may depend on comfort, drying skin, and/or annoyance, for example.

In an embodiment, the foam interface may be constructed to leak within predictable and predetermined limits and physical locations, e.g., vary air flow permeability or breathability around the outer perimeter of the interface. Also, the material of the foam may be selected to manage moisture, e.g., avoid moisture buildup in some regions and encourage moisture in other regions, e.g., near nose for humidification. Hydrophobic and hydrophilic (e.g., moisture wicking) materials (or treatments resulting in similar properties) are some options. Moisture wicking foam adapted to “pull” moisture or sweat from the patient's skin may decrease skin breakdown, pressure sores, and/or ulceration.

The foam may be designed to feature different degrees of air permeability through the bulk of the foam and through the surface of the foam. The foam may be impermeable through its body and permeable just at its interfacing surface. Conversely, the foam may be permeable through its body and impermeable at its interfacing surface, though resulting in different sealing characteristics. For example, this could allow breathability to be achieved while achieving alternative interfacing and/or sealing characteristics to the cut-cellular structured foam interface described herein. The foam may also be structured to be impermeable throughout, or impermeable in specific locations where airflow permeability is to be avoided, e.g., into the eyes.

The breathable interface may improve the dynamic interfacing performance (i.e., the ability to withstand macro-movement from a patient rolling around in bed and maintain an interface) over conventional interfacing materials. This is achieved because a small amount of airflow is already flowing between the interface surface and the patient's skin and there is less consequence to the interfacing mechanism when it is subjected to macro-movement compared to a conventional silicone seal. Silicone relies partially on its ability to “stick” to the patient's skin to provide a stable dynamic seal. Thus, when the silicone seal is moved tangentially along the skin surface, it is forced to buckle and completely detach from the skin and be reseated normally to the face to regain its geometrical form that it was designed to sit in to seal. That is, the silicone seal will provide an abrupt leak upon shifting or macro-movement that requires reseating of the interface, whereas the breathable foam interface provides an interface that can regain its interfacing properties easily without the need to reseat the foam interface on the patient's face to recover from its buckled geometry (e.g., from movement of the face relative to the interface). This is also an effect of having an interface that does not rely on membrane mechanics to interface and/or seal. The width of the cross-section of the interface may typically be an order of magnitude larger than a membrane thickness (preferably 5-12 mm and even more preferably 8-10 mm, as compared to 0.35-1.0 mm). The larger width may allow for the interface to engage with the patient's face over a larger area, and as such may not be as sensitive to a local disruption in the interfacing mechanism due to movement or surface irregularity on the patient's face. In addition, the cut surface of the foam interface provides lower tension transfer across the surface when it is compressed into the face, which is an improvement in dynamic sealing performance over silicone membrane seals which are susceptible to leakage due to creasing when they move on the face.

In an alternative embodiment, the foam interface may have a skinned surface, and the skinned surface may be permeable to provide similar effects as a foam interface having a cut, unskinned surface. For example, the skinned surface may in the form of a breathable polyurethane skin, a membrane that allows permeability, a textured surface, a spray-on porous coating, a perforated skin, and/or a textile. In another example, as shown in FIG. 13-8, the foam interface 80 may have a skinned surface SS, and a vent 81 may extend from the foam interior to atmosphere to allow permeability.

FIG. 14-2 is a graph that illustrates properties of a foam interface according to an embodiment of the present invention. As illustrated, the foam interface may be structured such that leak decreases as force applied to the interface (both in compression and extension) is increased. Also, the disruption to leak flow with movement away from the patient's face is minimal.

2.9 Compliance

The foam interface has a (mechanically) compliant nature that allows it to accommodate a much larger range of facial geometry compared to interfaces made of silicone and other materials known in the art. This arrangement allows for the possibility of consolidating the number of sizes required to fit a patient population, e.g., potentially a one-size-fits-all interface.

Because of the mechanical compliance of the bulk material, the foam seal conforms readily to a larger range of facial shapes as compared to a non-foam seal.

One way that compliance can be quantified is by measuring to what extent the bulk material wraps around a cylinder of a given diameter. More specifically, the angle the bulk material wraps around the cylinder can be measured with respect to the longitudinal axis of the cylinder.

A preferred foam according to an embodiment of the present invention has a cut or unskinned patient contacting surface and a thickness of between 8 and 14 mm and has a density of between 40 and 70 kg/cubic meter.

That is, the foam interface may provide superior mechanical compliance, and this combined with the fact that the region of interfacing is less complex and has less magnitude of anthropometric variation (e.g., compared to conventional nasal and full face interfaces) gives the interface superior fitting qualities. The foam can deform to the appropriate size and shape (e.g., localized deformation) without compromising the interface (e.g., buckling, creasing) and without adding discomfort to the patient (e.g., lower and more even pressure on the face). In addition, the highly compliant foam fits and interfaces with a broader range of population for a given geometry (e.g., size), especially compared to silicone interfaces. Further, the mechanical compliance of the foam interface can make the patient interface design less reliant on strap tension from headgear. In an embodiment, the patient interface may be fitted to the patient's face by fitting the air delivery and stabilizing system (e.g., headgear) and then allowing the interface to find its way to the patient's nose without the need for refined adjustments. That is, the foam interface better accommodates imprecise fitting.

The compliant nature of the foam also allows the foam to quickly adapt to the patient's face, (e.g., upon initial fitting or when the patient moves or rolls around during sleep), without compromising the interface and without adding discomfort to the patient. That is, the foam provides greater tolerance to misalignment.

2.10 Warming

The foam interface may provide a warming sensation to the patient's nares upon exhalation, e.g., similar to breathing into a blanket on a cold night. This arrangement reduces the “frozen nose” effect experienced by some users of nasal prong or nasal pillow interfaces. In an embodiment, the foam interface may include extended side portions that extend along sides of the patient's face, e.g., along upper cheek regions between the air delivery tubes and the patient's cheeks near or extending from the mouth, to provide the warming sensation to other areas of the patient's face.

2.11 Layers

In an embodiment, the interfacing structure may include a soft foam attached to a stiffer structure, e.g., 40 Shore A silicone shell with a wall thickness of approximately 1.5 mm such as the cylindrical support described in U.S. patent application Ser. No. 10/781,929, the entirety of which is incorporated herein by reference.

In another embodiment, the interfacing structure may include multiple layers with each layer providing a certain function. For example, FIG. 17-1 schematically illustrates an interfacing structure including four functional layers. The first layer L1 represents a skin-contacting layer that is structured to provide a comfortable seal against the skin of the patient's face and/or nose. The second layer L2 represents a conforming layer that is structured to easily conform to the patient's nasal anatomy. The third layer L3 represents a form holding layer that is structured to support the interface to hold its overall form (since the softness of the L1 and L2 layers may not be sufficiently self-supporting under loading conditions). The fourth layer L4 represents a retention/attachment layer that is structured to retain/attach the interfacing structure to the patient interface, e.g., frame, shell.

For simplicity, all functions would be provided by as few physical layers or components as possible. For example, the functionality of the skin contacting layer L1 and the conforming layer L2 may be provided by one material that includes both a comfortable feel on the skin and suitable plush compressive properties to conform around the underside of the nose. In another example, the reinforcing functionality of the L3 layer and the attachment functionality of the L4 layer may be provided by the (L4) attachment mechanism, and/or by the substrate (e.g., adhesive) used to join the functional layers together.

In an embodiment, such as that shown in FIGS. 13-1 and 13-2, the foam interface 80 with a cut cellular structure may provide the functionality of the first and second layers L1, L2, the cylindrical support 82 (e.g., made of silicone) may provide the functionality of the third layer L3, and a loop material for attachment to a frame may provide the functionality of the fourth layer L4 (described below).

In another embodiment, the L3 form holding layer may include a material that is malleable (e.g., aluminum wire) so that the interface may be manually deformed into a more effective and comfortable geometry.

In alternative embodiments, the first or skin contacting layer L1 may be flocked or covered with a textile (or other suitable breathable materials), e.g., for comfort, grip, alternative wicking properties, and/or alternative air permeability.

2.12 Attachment Mechanism

In the illustrated embodiment, the interfacing structure 20 is a separate component from the air delivery and stabilizing system 30. Therefore, an attachment mechanism is provided to secure (e.g., removably secure) the interfacing structure to the air delivery and stabilizing system. As noted above, a portion of the attachment mechanism may form a retention layer L4 of the interfacing structure.

2.12.1 General Physical Requirements

The interface component is typically a separate component to the rest of the patient interface. This is due to many reasons including: the interface geometry is usually complex and difficult to manufacture in combination with other components of the patient interface; interfaces usually need to accommodate a large anthropometric variation and as such several interchangeable interface sizes exist to cover the full range of variation; the interface may require washing many times during its life and having it removable allows for a more thorough wash and makes cleaning an easier task; and/or interface has a replacement frequency greater than that of the rest of the patient interface and needs to be removable to be replaced.

The attachment mechanism is structured such that all assembly and disassembly tasks performed by the patient should be as easy as possible, particularly considering the potentially varied ages and intellectual and physical competencies of the patient.

For ease of assembly, elements of orientation, alignment, and force are considered in the design. In an embodiment, the interface includes as little asymmetry as possible (e.g., allowing functionally correct attachment in as many different (e.g., two) orientations as possible), intuitive cues as to the method of attachment (e.g., self-aligning or self-orienting), a size, shape, and texture that is not difficult to handle (e.g., requiring minimal dexterity), tolerance to misalignment, as little force as possible to assemble, and/or as little force as possible to disassemble. A force feedback from a mechanism usually can indicate to a user that assembly has occurred and is correct. While requiring as little force as possible to assemble, a correct assembly should be evident to the patient.

If assembly force is very low, disassembly force should be higher than the assembly force to ensure that disassembly does not occur inadvertently. Disassembly force should not be too high as to risk damage to the interface component or other components of the patient interface.

The attachment of the interface to the frame of the patient interface should have no air leak (e.g., sealed) or a small, known amount of air leak over the treatment pressure range.

In an embodiment, as shown in FIG. 17-2, the foam interface 80 may be provided to a base B adapted to retain the foam interface to a frame F. As illustrated, the base B is sufficiently longer than an inlet to the frame (e.g., length D of base is longer than length d of frame inlet) such that the base B is resiliently squeezed and/or simply manipulated through the inlet and into a slot S provided in the frame F where it is retained in an operative position.

In another embodiment, as shown in FIGS. 17-3A to 17-3C, a mechanical interference type attachment mechanism may removably attach the interfacing structure to the patient interface. As illustrated, a base B (e.g. stiff laminate) may be provided on the under side of the interfacing structure (e.g., in the form of a foam interface 180) and an attachment structure AT may be provided to the frame of the patient interface.

As illustrated, a hook portion HP extends from the inner edge of the attachment structure AT. In use, the base B is resiliently stretched and/or simply manipulated over the hook portion HP where it is retained in an operative position, e.g., with a mechanical interference fit. As shown in FIG. 17-3C, the free end 185 of the hook portion HP overhangs the inner edge of the base B to prevent inadvertent removal.

Also, the free end 185 of the hook portion HP provides an internal lip that is pressed against the foam interface 180 to provide a seal. Thus, the base B and attachment structure AT provide both attachment and a circumferential seal between the interfacing structure and the frame.

In the illustrated embodiment, the base B and attachment structure AT each have a generally planar configuration and the profile of the base B and attachment structure AT is substantially similar to the profile of the under side of the interfacing structure, e.g., elongated or elliptical ring shape.

As illustrated, the outer edges of the base B and attachment structure AT substantially align with outer edges of the under side of the foam interface 180. The inner edges of the attachment structure AT may be slightly external to inner edges of the under side of the foam interface 180, e.g., due to the hook portion HP.

However, other suitable perimeter boundaries are possible. For example, the coverage of the base B and attachment structure AT on the under side of the interfacing structure may be matched, internal, or external to the inner and outer edges of the under side geometry profile. In an embodiment, the base and attachment structure may be internal to the outer edge of the under side to prevent contact of the base and attachment structure with the patient's top lip in use.

The mechanical interference type attachment mechanism may have other suitable arrangements. For example, the mechanical interference type attachment mechanism may include: an internal lip with a sleeve section; an internal lip with angle section; an external lip with a single reinforcement layer; an external lip with a double reinforcement layer; a push-in fit with a single foam layer; or a push-in fit with a double foam layer.

In yet another embodiment, an adhesive type attachment mechanism may removably attach the interfacing structure to the patient interface. For example, an adhesive (e.g. pressure sensitive adhesive (PSA)) may be provided on the under side of the interfacing structure (e.g., in the form of a foam interface) that allows the interfacing structure to be removably attached to the frame of the patient interface.

In an embodiment, the under side and adhesive (e.g., PSA) provide thereto may have a generally planar configuration. In another embodiment, the under side and adhesive may provide a curvature along a first direction. In another exemplary embodiment, the base and adhesive may provide curvature along two or more directions, e.g., saddle shape over centering action.

The coverage of the adhesive on the under side of the interfacing structure may be matched, internal, or external to the inner and outer edges of the under side geometry profile. In an embodiment, the adhesive may be matched to the edges of the profile for ease of manufacture. In another embodiment, the adhesive may be internal to the outer edge of the under side to prevent contact of the adhesive with the patient's top lip in use.

In another embodiment, the attachment mechanism may be structured to manipulate the life span of the interface, e.g., attachment mechanism fails at a predetermined time and therefore requires replacement of the interface.

In another embodiment, no significant attachment mechanism may be provided as the interface is sandwiched between the frame and the patient's face in use.

2.12.2 Hook and Loop Material

In an embodiment, the attachment mechanism may be in the form of a hook and loop material, e.g., Velcro™. For example, the hook material may be provided on the frame and the loop material, e.g., UnBroken Loop (UBL), may be provided on the under side or base of the interfacing structure. For example, the loop material may be provided on the underside of the cylindrical support 82, e.g., by an adhesive.

This arrangement of the hook and loop material may be reversed, but in the context of an interface that has a high replacement frequency, it is preferred that the less durable side of the hook and loop material is attached to the interfacing structure, i.e., the loop material. A hook and loop style attachment mechanism allows for an intuitive assembly that requires very little force for assembly/disassembly.

A hook and loop interface typically is not airtight. Therefore, a hook and loop interface according to an embodiment of the present invention may include a small, known amount of leak that is repeatable within a defined range between assembly actions.

In an alternative embodiment, the attachment and interface-to-frame sealing functions may be performed separately. For example, a hook and loop interface may be used to provide the attachment, and a soft deformable closed loop linear interface may be used to provide the sealing. The hook and loop interface provides attachment between the interfacing structure and the frame and in doing so provides a normal force that presses the loop material onto a soft circumferential seal on the opposing side of the interface-to-frame arrangement. The interfacing structure may lie either on or adjacent to the hook material provided to the frame.

In another embodiment, instead of the interface or seal pressing against the loop material, the loop material may have a matching smooth rubber/plastic surface for the interfacing or sealing to work against.

In an exemplary embodiment, the interfacing structure may be formed by providing a sheet of foam material (e.g., slabstock or block of foam material (e.g., 1 m×0.5 m×2 m block)), laminating or otherwise attaching hook material to the foam sheet, and die cutting the foam sheet to form the desired shape of the interfacing structure.

FIGS. 17-4A to 17-4C illustrate another embodiment of a hook and loop type attachment mechanism (e.g., Velcro™) structured to removably attach the interfacing structure to the patient interface. As illustrated, a loop material LP may be provided on the under side of the interfacing structure (e.g., in the form of a foam interface 180) and a hook material HK may be provided to the frame of the patient interface. It should be appreciated that the arrangement of the hook and loop material may be reversed.

As illustrated, a sealing lip SL extends from the inner edge of the hook material HK. In use, the hook and loop materials are removably engaged with one another, which presses the loop material LP against the sealing lip SL to provide a seal. Thus, the hook and loop type attachment mechanism provides attachment between the interfacing structure and the frame, and the sealing lip SL is deformable to provide a circumferential seal between the interfacing structure and the frame.

In the illustrated embodiment, the hook and loop material HK, LP each have a generally planar configuration and the profile of the hook and loop material HK, LP is substantially similar to the profile of the under side of the interfacing structure, e.g., elongated or elliptical ring shape.

As illustrated, the inner and outer edges of the hook and loop material substantially align with inner and outer edges of the under side of the foam interface 180. That is, the perimeter boundaries of the hook and loop material may be matched to the edges of the under side geometry profile of the interface, e.g., for ease of manufacture.

However, other suitable perimeter boundaries are possible. For example, the coverage of the hook and loop material on the under side of the interfacing structure may be matched, internal, or external to the inner and outer edges of the under side geometry profile. In an embodiment, the hook and loop material may be internal to the outer edge of the under side to prevent contact of the hook and loop material with the patient's top lip in use.

The hook and loop type attachment mechanism may have other suitable arrangements. For example, the hook and loop materials may provide a planar configuration such as that described above, but without a sealing lip. In another exemplary embodiment, the hook and loop materials may provide a curvature along a first direction. In another exemplary embodiment, the hook and loop materials may provide a curvature along a first direction and a sealing lip such as that described above. In yet another exemplary embodiment, the hook and loop materials may provide curvature along two or more directions, e.g., saddle shape over centering action.

2.12.3 Snap-over Low Retention

FIGS. 18-1 to 18-3 illustrate a method of joining an under-the-nose foam interface 380 to a frame 322 according to another embodiment of the present invention. In this embodiment, the under-the-nose interface 380 includes structure that allows it to be attached to the frame 322 with a snap-over fit, and the connection relies on the friction and/or mechanical interlock between the under-the-nose interface 380 and frame 322 for its strength. The resultant joint would have limited strength, however the location of the joint allows the force between the patient and the frame to assist in strengthening the joint.

As shown in FIGS. 18-1 and 18-2, the frame 322 includes a generally tubular structure that is curved along its length so that it can follow the contours and/or conform to the shape of the patient's face in use. As shown in FIGS. 18-2 and 18-3, the under-the-nose interface 380 is structured so that it can be attached to the frame 322 with a snap-over fit. Specifically, the back side of the under-the-nose interface 380 includes a groove 387 along its longitudinal axis that is adapted to receive a portion of the tubular frame 322 therein. One or more surfaces and/or edges of the groove 387 are adapted to engage the frame 322 with a friction and/or mechanical interlock fit. Also, each end of the under-the-nose interface 380 includes an arcuate cutout 389 that is adapted to receive a respective end portion of the frame 322 as it curves along its length.

2.12.4 Snap-over with PSA

In another embodiment, an under-the-nose interface or foam interface may be joined to a frame by a pressure sensitive adhesive (PSA). FIGS. 19-1 to 19-3 are sequential views illustrating a manufacturing process for applying PSA to the back of an under-the-nose interface according to an embodiment of the present invention. FIG. 19-1 illustrates an untreated under-the-nose interface 480, FIG. 19-2 illustrates an under-the-nose interface 480 after a PSA 485 has been applied, and FIG. 19-3 illustrates the finished sub-assembly after a removable backing 486 has been applied to the PSA 485 on the under-the-nose interface 480.

The under-the-nose interface 480 would be assembled in a similar manner as that shown in FIGS. 18-1 to 18-3, e.g., snap-over fit. In contrast, the backing 486 is removed from the under-the-nose interface 480 before assembly in order to reveal the PSA 485. The resultant joint will have increased joint strength with the PSA 485. When choosing a PSA, the PSA should be configured such that it adheres better to the under-the-nose interface than to the frame. That is, the cohesive strength of the PSA is preferably higher than the adhesive strength. This arrangement allows the PSA to remain on the under-the-nose interface and not on the frame when the under-the-nose interface is pulled off from the frame, e.g., for cleaning or replacement.

2.12.5 Snap-Over with Groove or Undercut

FIGS. 20-1 to 20-3 illustrate a method of joining an under-the-nose interface or foam interface 580 to a frame 522 according to another embodiment of the present invention. In this embodiment, the under-the-nose interface 580 includes a groove or undercut 595 on opposing sides thereof that is adapted to mate or interlock with respective protrusions 596 provided on the frame 522, e.g., with a snap-fit. The resultant joint will have increased joint strength with respect to that shown in FIGS. 18-1 to 18-3 for example.

In an alternative embodiment, the under-the-nose interface may provide a composite snap-over arrangement. For example, FIGS. 20-4 to 20-7 are sequential views illustrating a manufacturing process for forming a composite under-the-nose interface according to an embodiment of the present invention. In FIG. 20-4, a visco-elastic foam portion 1291 is formed having a first side that provides a patient interface and a second side that provides spaced apart platforms 1293. In FIG. 20-5, connecting portions 1297 are formed each having a groove or undercut 1295. The connecting portions 1297 are constructed from a material having a lot more resilience and structure than the visco-elastic foam portion 1291, e.g., high density foam, TPE, TP. In FIG. 20-6, an adhesive 1285, e.g., hot melt glue, is applied to each of the platforms 1293 of the foam portion 1291. Then, as shown in FIG. 20-7, the connecting portions 1297 are attached to respective platforms 1293 of the foam portion 1291 via the adhesive 1285 to assemble the composite under-the-nose interface 1280. In use, the composite under-the-nose interface 1280 may be attached to a frame such as that described in FIGS. 20-1 to 20-3, e.g., groove or undercut 1295 interlocks with respective protrusions provided on the frame. The composite under-the-nose interface 1280 provides connecting portions 1297 that are structured to provide a higher joint strength than visco-elastic foam alone. It should be appreciated that other suitable manufacturing processes may be used to create a composite under-the-nose interface.

In yet another embodiment, the attachment mechanism may be structured to allow the foam of the interface to be received into a receiving channel in the frame or shell. The seal and retention in this case relies upon the interference fit between the foam and the channel in the frame or shell. The very soft interfacing foam is preferably laminated or otherwise joined to a harder and more dense foam (or other structure) that results in a greater interference force when engaged with the channel.

In another embodiment, the attachment mechanism can be achieved through a rigid or semi-rigid component adhered to the underside of the soft interfacing foam. The rigid/semi-rigid component may be configured to provide a number of mechanical interference fits, e.g., clipped into/onto frame.

2.12.6 Magnetic Arrangement

In an alternative embodiment, the attachment mechanism may include a magnetic arrangement to magnetically couple the frame and the interfacing structure.

2.13 Structural Compliance

2.13.1 Background

The topography around the nose has steep gradients with sharp transitions between these gradients. For an interface to be most effective, it needs to be flush with all surfaces to achieve an interface, e.g., seal. A low resilience structure would allow the greatest comfort while still achieving an interface, e.g., textile interface. However, textile interfaces are typically very thin (e.g., less then 2 mm thick) and cannot in themselves offer the required properties to add compliance. In order for a textile interface to conform to the patient's face, a support structure is required. However, a support structure is not limited to textile interfaces, i.e., foam and silicone interfaces to name a few could benefit from a support structure as well.

2.13.2 Flexible Frame

In an embodiment, the interface may be mounted on a frame made from a flexible material, e.g., injection molded silicone frame. Each end of the frame would be attached to a respective tube 42. When pulled against the patient's face, the flexible frame can conform to the patient's face, e.g., wrap around the patient's nose without pinching.

The frame may be constructed of materials having different stiffnesses. If the frame is constructed of silicone, this arrangement may be achieved by simply using silicones with different Shore Hardnesses.

For example, FIGS. 21-1 to 21-3 illustrate a frame 622 for supporting an under-the-nose interface 680 and vent 627 according to an embodiment of the present invention. As best shown in FIGS. 21-2 and 21-3, the central portion C of the frame 622 (shown in darker shading) is stiffer than the side portions S of the frame 622.

This arrangement results in side portions S having more flexibility than the center portion C of the frame 622. As shown in FIG. 21-3, as a force applied to the frame 622 is increased, the deflection of the side portions S is more substantial than that in the center portion C. As a result, the frame 622 will not pinch the patient's nose and the center portion C will remain relatively straight to prevent the interface from occluding the nostrils. In addition, the stiffer center portion C ensures that the conduit in front on the patient's nose is maintained open in use.

FIG. 22-1 illustrates a flexible frame 722 according to another embodiment of the present invention. In this embodiment, the frame 722 may be a molded foam conduit including openings 722.1 and 722.2 adapted to engage an under-the-nose interface, e.g., replaceable foam under-the-nose interface, and vent. The ends of the frame 722 may attach to respective tubes 42 in any suitable manner.

2.13.3 Flexible Frame with Spring Element

In another embodiment, a flexible frame such as those described above may include a spring element to increase comfort. For example, FIG. 23-1 illustrates a flexible frame 822 including a spring element 828 and an interface 880 provided to the frame 822. The spring element 828 may be a thermoplastic elastomer (TPE) or a metal (e.g., Polycarb, Nitinol, etc.). In the illustrated embodiment, the spring element 828 is attached horizontally along the frame 822. However, other suitable arrangements are possible. In use, the spring element 828 is structured to counteract the force provided by the air delivery and stabilizing system 30, e.g., tubes 42. The spring element will effectively increase the radius of the frame 822 when attached to the patient.

In an embodiment, the spring element may be a variable spring element that varies its k values across its length, e.g., see graph of FIG. 23-2. As illustrated, the spring element may have a k that resembles a general bell curve arrangement such that the middle of the spring element is relatively stiff and the ends of the spring element are relatively loose. This arrangement may be advantageous as the curvature of the patient could be better matched. For example, if the interface was an under the nose type interface, a relatively stiff spring may be provided in the middle of the frame and then a loosening spring may be provided as the frame moves away from the center of the nares.

To add further compliance, a low resilience foam may be added between the spring element and the interface. For example, FIG. 23-3 illustrates an interface 980 provided to a frame having a low resilience foam 956, a medium density foam 957, and spring elements 929, e.g., constructed of Nitinol.

2.14 Venting

In an embodiment, a breathable foam interface may provide the necessary volume of CO₂ washout or venting, which may obviate the need for separate CO₂ washout vents. In addition, the breathable foam interface may provide a vent silencing or diffusing feature. Thus, the breathable foam interface may provide a single component with dual purposes, e.g., sealing and venting. However, CO₂ vent holes may be used in conjunction with a foam interface, e.g., because condensation may block one or more breathable portions of the breathable foam interface. The air venting from the CO₂ vent holes may pass through the foam as a means of diffusing and reducing noise from the stream of venting air.

For example, the frame or support that supports the foam interface may include one or more vent holes for CO₂ washout, e.g., see FIGS. 1-8, 2-1, and 18-1.

Also, FIG. 24-1 illustrates a foam interface 1080 including a rigidizer 1098 that provides venting. The rigidizer 1098 may be in the form of a rigid/semi-rigid backing piece including holes 1099 for venting. As illustrated, the foam interface 1080 includes a “boomerang” shape. The semi-porous nature of the foam and the extended arms of the “boomerang” shape allows the patient's skin to breathe under the foam, as the foam has a very small and diffuse flow of air constantly coming out of the foam from the orifice outwards.

Further, in an alternative embodiment, the frame or support that supports the foam interface may include one or more supplemental ports, e.g., to provide supplemental oxygen and/or collect pressure/humidity data.

2.15 Alternative Interfacing Arrangements

It should be appreciated that the interfacing structure may have other interfacing arrangements. That is, the foam interface type is merely exemplary, and the foam interface may be adapted for use with other suitable interface types, e.g., over-the-nose interface, nasal cushion, mouth, full-face, nasal prongs, etc. For example, FIG. 25-1 illustrates an embodiment of a patient interface 1110 including an under-the-nose interface 1180 and a mouth interface 1181, e.g., constructed of foam, to interface or seal with the patient's mouth in use.

2.16 Foamed Silicone

In lieu of and/or in addition to using visco-elastic foam (e.g., polyurethane) as discussed above, various components of the patient interface may be constructed at least in part from a silicone that is foamed, i.e. foamed silicone. That is, one or more portions of a component may be constructed from foamed silicone or an entire component may be constructed from foamed silicone.

For example, a forehead pad for a forehead support of a patient interface includes a stalk or connector adapted to connect the forehead pad to a frame and a patient-contacting pad portion adapted to contact the patient's forehead. In an embodiment, the stalk may be constructed from a non-foamed silicone (e.g., LSR) and the patient-contacting pad portion may be constructed from a foamed silicone.

In other examples, the cushion of the patient interface and/or conduits connected to the patient interface may be partly or wholly constructed from foamed silicone.

The foamed silicone can provide respective components with different “feels” and/or different connection properties.

For example, foamed silicone may provide one or more of the following properties: lighter; appealing texture, comfort; uses less material; opaque or translucent; cleanable (e.g., if there are a sufficiently high percentage of closed cells) to make the component longer lasting and with a lower replacement frequency; softer at a given thickness or durometer; lower extensibility and tear resistance; surface properties may be altered (e.g., with a skin); impermeable to air/biological matter; permanence of sealing properties with age (e.g., oil/grease absorbance); and/or surface breathable but body impermeable.

3. Application to Known Masks

One or more aspects or features of the present invention may be adapted for use and/or incorporated into embodiments and/or components of known masks, as would be apparent to those of ordinary skill in the art.

3.1 Respironics' ComfortCurve™

FIG. 26-1 illustrates a known mask 1500 commercially sold by Respironics Inc. under the name of ComfortCurve™ and one or more portions of the mask are described in Australian Application No. AU 2005100738, published Nov. 24, 2005. As illustrated, the mask 1500 includes a frame 1502, a cushion 1504 provided to the frame 1502 and adapted to form a seal with the patient's nose in use, cheek pads 1506 provided to the frame 1502 to support the cushion 1504 in use, inlet tubes 1508 provided to the frame 1502 and adapted to deliver breathable gas to the patient, and headgear 1505 removably attached to the frame 1502 to maintain the mask 1500 in a desired position on the patient's face.

3.1.0 Improvements/Alternative Arrangements

The following embodiments describe improvements and/or alternative arrangements of Respironics' ComfortCurve™ mask to enhance respiratory therapy.

3.1.1 Foam Seal

The ComfortCurve™ mask includes a cushion constructed of a silicone material. In an alternative embodiment, as shown in FIG. 26-2, the cushion may be a foam cushion 1504F constructed of a foam material F. The foam material F may include one or more of the foam properties described above, e.g., visco-elastic, un-skinned, etc.

In such embodiment, the frame attachment mechanism or clip 1507 may be maintained as a base substrate and the foam material F may be attached to the clip 1507. This arrangement allows removable attachment of the foam cushion to the existing frame of the ComfortCurve™ mask.

In an embodiment, as shown in FIG. 26-3, the foam cushion 1504F may extend along side portions of the frame 1502 (e.g., in place of the cheek pads 1506) so that the foam material F may wrap around the patient's nose and/or conform to the patient's face when the frame 1502 is pulled against the patient's face in use.

In an embodiment, the foam cushion 1504F may include multiple layers, e.g., a first layer constructed of a high density foam and a second layer constructed of a more compliant foam adapted to engage the patient's face.

In another embodiment, as shown in FIG. 26-4, the ComfortCurve™ cushion 1504 may be provided with a foam or fabric layer FL on a contact surface adapted to engage the patient's face. The foam or fabric layer FL may be provided to the cushion in any suitable manner, e.g., spray-on foam like flocking, fabric adhered to cushion, etc. The foam or fabric layer FL may improve comfort, feel, and/or softness, and may provide a moisture wicking feature.

3.1.2 Conduit Headgear

The ComfortCurve™ mask includes headgear constructed of a fabric-type material to maintain the mask in a desired position on the patient's face. In an alternative embodiment, as shown in FIG. 26-5, the headgear may be replaced or combined with collapsible conduits 1540 adapted to deliver breathable gas and stabilize the cushion interface on the patient's face. The conduits 1540 may include one or more of the tube properties described above, e.g., partially or fully collapsible, cross-sectional contour that blends into the patient's face, etc., and/or the conduits 1540 may include a rigidizer.

3.1.3 Tube Routing

In another embodiment, as shown in FIG. 26-6, the inlet tubes 1508 may be routed through the headgear 1505, e.g., up towards the top of the patient's head, rather than hang downwardly from the frame.

In such embodiment, a support member may be provided to the headgear to improve stability. For example, a wire member (e.g., magnesium wire) may be provided to the headgear straps that extend from the frame to top of the patient's head.

3.1.4 Soft Material on Headgear Strap

In another embodiment, as shown in FIG. 26-7, one or more straps of the headgear 1505 may include a relatively soft cover, sock, or pad 1509, e.g., constructed of foam or gel, to improve comfort.

3.1.5 Inlet Tubes Attached to Cheek Pads

In another embodiment, as shown in FIG. 26-8, the cheek pads 1506 may be inflatable and the inlet tubes 1508 may be attached or otherwise communicated to the cheek pads 1506 to inflate the cheek pads 1506 in use. Such an arrangement may be adapted for use with the conduit headgear described above.

Also, in an embodiment, the cheek pads may be in fluid communication with the cushion such that air may pass from the inlet tubes and into both the cushion cavity and cheek pads.

3.1.6 Inlet Tubing Along Inside of Frame/Headgear

In another embodiment, the inlet tubes may extend along an inner side of the frame (e.g., adjacent the patient's face) and/or the headgear, rather than along the outer side of the patient's face.

3.1.7 Accommodate Alar and Naso-Labial Angle

In another embodiment, the cushion may be structured to accommodate the alar and naso-labial angle of the patient's nose.

3.1.8 Eliminate Cheek Pads

In another embodiment, the cheek pads may be eliminated. In such embodiment, as shown in FIG. 26-9, a yoke or rigidizer 1511 may be provided one or more straps of the headgear 1505 to improve stability. For example, the rigidizer may be structured similar to that provided on ResMed's VISTA™ and SWIFT™ masks, e.g., see U.S. Pat. No. 6,907,882 and U.S. patent application Ser. No. 10/781,929, filed Feb. 20, 2004, each of which is incorporated herein by reference in its entirety.

In an embodiment, the rigidizer 1511, frame 1502, and inlet ports 1514 associated with inlet tubes 1508 may be integrally formed as a one-piece structure.

In another embodiment, the cheek pads may be eliminated and the frame may be extended to improve stability. For example, as shown in FIG. 26-10, the frame may include extended side portions 1513 that extend along the sides of the patient's head and taper/thin out towards the patient's temple. Ends of the side portions 1513 may include suitable structure for attachment to respective headgear straps.

3.2 Respironics OptiLife™

FIG. 27-1 illustrates another known mask 1600 commercially sold by Respironics under the name of OptiLife™. As illustrated, the mask 1600 includes a frame 1602, nasal pillows 1604 provided to the frame 1602 and adapted to form a seal with the patient's nasal passages in use, an inlet tube 1608 provided to the frame 1602 and adapted to deliver breathable gas to the patient, and headgear 1605 including a chin strap 1606 removably attached to the frame 1602 to maintain the mask 1600 in a desired position on the patient's face.

3.2.0 Improvements/Alternative Arrangements

The following embodiments describe improvements and/or alternative arrangements of Respironics' OptiLife™ mask to enhance respiratory therapy.

3.2.1 Foam Interface

The OptiLife™ mask includes nasal pillows. In an alternative embodiment, as shown in FIG. 27-2, the nasal pillows may be replaced with a foam interface F constructed of a foam material F. The foam interface F may include one or more of the foam properties described above, e.g., visco-elastic, de-skinned, etc.

In such embodiment, the foam interface F may be provided with an adaptor having a base that supports the foam interface F and couples the foam interface F to the existing frame 1602 of the OptiLife™ mask.

3.2.2 Foam Cheek Pads

In another embodiment, as shown in FIG. 27-3, each side strap of the headgear 1605 may include a foam cheek pad 1607 to improve comfort and/or stability.

3.2.3 Side Inlet Ports

In another embodiment, as shown in FIG. 27-4, the frame 1602 may include side inlet ports 1614 adapted to engage respective inlet tubes 1608. For example, the frame may be structured similar to that provided on Respironics' ComfortCurve™ mask.

3.2.4 Collapsible Inlet Tubes

In another embodiment, as shown in FIG. 27-5, the frame 1602 may include side inlet ports 1614 adapted to engage collapsible inlet tubes 1640 including one or more of the collapsible tube properties described above.

In an embodiment, the collapsible inlet tubes 1640 may be routed through the headgear 1605, e.g., up towards the top of the patient's head.

3.2.5 Rigidizers

In another embodiment, as shown in FIG. 27-6, a rigidizer 1611 may be provided one or more straps of the headgear 1605 to improve rigidity and/or stability.

3.2.6 Gap-filling Structure

In another embodiment, the mask may include structure (e.g., provided to the headgear, frame, etc.) that is adapted to fill gaps or spaces provided between the patient's face and the mask/headgear. The gap-filling structure may improve comfort and/or stability in use. For example, as shown in FIG. 27-7, the mask may include structure to fill gaps or spaces S provided between the patient's face and the mask/headgear.

3.3 Respironics' ComfortLite™ and ComfortLite™ 2

FIG. 28-1A illustrates a known mask commercially sold by Respironics' under the name of ComfortLite™ and FIG. 28-1B illustrates a known mask commercially sold by Respironics' under the name of ComfortLite™ 2. As illustrated, the ComfortLite™ and ComfortLite™ 2 masks 1700 each include a frame 1702, nasal pillows 1704 provided to the frame 1702 and adapted to form a seal with the patient's nasal passages in use, an inlet tube 1708 provided to the frame 1702 and adapted to deliver breathable gas to the patient, and headgear 1705 to maintain the mask 1700 in a desired position on the patient's face.

3.3.0 Improvements/Alternative Arrangements

The following embodiments describe improvements and/or alternative arrangements of Respironics' ComfortLite™ and ComfortLite™ 2 masks to enhance respiratory therapy.

3.3.1 Two Tube Arrangement

In another embodiment, each mask may include two inlet tubes rather than a single inlet tube that extends over the patient's nose to the top of the patient's head. For example, as shown in FIGS. 28-2A and 28-2B, the frame 1702 may include side inlet ports 1714 adapted to engage respective inlet tubes 1708 routed towards the top of the patient's head.

In such embodiment, one or more portions of the headgear may be eliminated such as the forehead support.

3.4 Fisher & Paykel's Opus™

FIG. 29-1 illustrates another known mask 1800 commercially sold by Fisher & Paykel under the name of Opus™. As illustrated, the mask 1800 includes a frame 1802, nasal pillows 1804 provided to the frame 1802 and adapted to form a seal with the patient's nasal passages in use, an elbow 1807 provided to the frame 1802 and connected to an inlet tube 1808 adapted to deliver breathable gas to the patient, and headgear 1805 including a support structure or rigidizer 1809 to maintain the mask 1800 in a desired position on the patient's face.

3.4.0 Improvements/Alternative Arrangements

The following embodiments describe improvements and/or alternative arrangements of Fisher & Paykel's Opus™ mask to enhance respiratory therapy.

3.4.1 Quick Release

The frame 1802, nasal pillows 1804, and elbow 1807 of the Opus™ mask form a sub-assembly that is coupled to the support structure 1809 via a clip arrangement. In an alternative embodiment, quick release arrangements may be provided to releasably connect the sub-assembly to the support structure. For example, the sub-assembly may be coupled to the support structure via a magnet arrangement.

In another embodiment, the sub-assembly may be coupled to the support structure in a manner that allows removal of the sub-assembly while the headgear is maintained on the patient's head.

In another embodiment, the joint between the elbow and the frame can be structured in a quick-release design, e.g., where the ball joint of the elbow can be resiliently attached/detached from the frame. This arrangement allows the frame/nasal pillows to be maintained along with the headgear on the patient's head.

As shown in FIG. 29-2, the clip arrangement of the Opus™ mask includes a clip 1817 on the bottom portion of the frame 1802 that is adapted to engage a clip receptacle 1819 provided to the support structure 1809. In an alternative embodiment, as shown in FIG. 29-3, the clip arrangement may have a reverse position, e.g., clip 1817 provided to a top portion of the frame 1802. This arrangement may allow a more continuous form across the front of the mask.

In another embodiment, as shown in FIG. 29-4, the clip arrangement may be arranged to allow the sub-assembly to engage the support structure 1809 from the front of the support structure, rather than from the rear of the support structure (e.g. see FIG. 29-2).

In another embodiment, as shown in FIG. 29-5, the support structure may provide an annular ring 1821 that is adapted to engage a resilient mating portion or snap-fit connector 1823 provided to the frame 1802. The snap-fit arrangement may be similar to the elbow connection arrangement of ResMed's VISTA™ mask, e.g., see U.S. Pat. No. 6,907,882 which is incorporated herein by reference in its entirety.

In yet another embodiment, as shown in FIG. 29-6, one of the frame 1802 and support structure 1809 may include a flange (e.g., flange F on frame as shown in FIG. 29-6) and the other of the frame 1802 and support structure 1809 may include a recess (e.g., recess R on support structure as shown in FIG. 29-6) adapted to receive the flange to retain the frame to the support structure.

3.4.2 Adjustment Mechanism

In another embodiment, an adjustment mechanism may be provided to the frame and/or nasal pillows to allow adjustment of the nasal pillows to accommodate the alar and naso-labial angle of the patient's nose.

3.4.3 Slidable Elbow/Inlet Tube

In another embodiment, the elbow and/or tube may be arranged for sliding movement relative to the frame to isolate the seal from tube drag. For example, FIG. 29-7 illustrates a slidable elbow 18075 that is slidable with respect to the frame 1802 into multiple operative positions, e.g., 2 or more operative positions.

3.4.4 Low Profile Elbow

In another embodiment, a portion of the elbow may have a substantially oval-shaped cross-section (rather than a round cross-section) to provide the elbow with a lower profile.

3.4.5 Tube Routing

In another embodiment, the mask may include two inlet tubes rather than a single inlet tube. For example, as shown in FIG. 29-8 the frame 1802 may include side inlet ports 1814 adapted to engage respective inlet tubes 1808 routed towards the top of the patient's head.

In such embodiments, the headgear may be eliminated or integrated with the tubes, e.g., two inlet tubes adapted to deliver breathable gas and stabilize the nasal pillows on the patient's face.

Also, the inlet tubes may be collapsible and may include one or more of the collapsible tube properties described above.

3.4.6 Foam Seal

In an alternative embodiment, as shown in FIG. 29-9, the silicone nasal pillows of the Opus™ mask may be replaced with a foam interface 1815 constructed of foam F and including one or more of the foam properties described above.

In an embodiment, the foam interface may be a block of foam (e.g., reticulated foam) wherein the perimeter of the interface is sealed or relatively less permeable and the center of the interface is breathable to act as diffusing mechanism. In such embodiment, the center of the interface may have two discrete areas for each nostril.

Other foam alternatives include edible packaging foams, fibrous filter material, and foam prongs. The foam prongs may have a bell shape with a cylindrical outlet hole, and optional reinforcement may be provided to one or more portions of the foam prongs, e.g., inner walls, outer walls, etc.

In another embodiment, the silicone nasal pillows may be provided with a foam layer on a contact surface adapted to engage the patient's nose. The foam layer may be provided to the nasal pillows in any suitable manner, e.g., spray-on micro diffuse layer (e.g., HC405). The foam layer may improve comfort, feel, and/or softness, and may provide a moisture wicking feature.

3.5 Puritan Bennett's Breeze® SleepGear® DreamSeal®

FIGS. 30-1 and 30-2 illustrate another known mask 1900 commercially sold by Puritan Bennett under the name of Breeze® SleepGear® DreamSeal®. As illustrated, the mask 1900 includes a frame 1902, a cushion 1904 provided to the frame 1902 and adapted to form a seal with the patient's nose in use, an inlet tube 1908 provided to the frame 1902 and adapted to deliver breathable gas to the patient, and a head support 1905 provided to the frame 1902 to maintain the mask 1900 in a desired position on the patient's face.

3.5.0 Improvements/Alternative Arrangements

The following embodiments describe improvements and/or alternative arrangements of Puritan Bennett's Breeze® SleepGear® DreamSeal® mask to enhance respiratory therapy.

3.5.1 Foam Seal

The Breeze® SleepGear® DreamSeal® mask includes a cushion constructed of a silicone material. In an alternative embodiment, as shown in FIG. 30-3, the cushion may be a foam cushion 1904F constructed of a foam material F. The foam material F may include one or more of the foam properties described above, e.g., visco-elastic, un-skinned, etc.

3.5.2 One-piece Tube/Head Support

The head support 1905 of the Breeze® SleepGear® DreamSeal® mask includes a metal spring 1911 that supports a cradle 1913 adapted to engage the rear the patient's head (e.g., see FIG. 30-1). In an alternative embodiment, the metal spring 1911 may be replaced with a plastic component that may be molded in one-piece with the remainder of the head support. In addition, the one-piece head support may be overmolded with the inlet tube 1908, e.g., to reduce the number of parts, facilitate assembly, etc.

3.5.3 Lower Profile

As shown in FIG. 30-2, the Breeze® SleepGear® DreamSeal® mask includes a gap G between the inlet tube 1908 and the nose/forehead of the patient's face. In an alternative embodiment, the gap G may be reduced by changing the contour and/or routing of the inlet tube 1908. For example, as shown in FIG. 30-4, the inlet tube 1908 may be flatter towards the top of the patient's head (e.g., more oval-shaped cross-section 1917 as opposed to round-shaped cross-section 1919) and have a configuration such that it provides narrower portion 1921 as it passes between the patient's eyes (e.g., hourglass-shaped).

3.5.4 Two Tube Arrangement

In another embodiment, the mask may include two inlet tubes rather than a single inlet tube. For example, as shown in FIG. 30-5, the frame 1902 may include side inlet ports 1914 adapted to engage respective inlet tubes 1908 routed towards the top of the patient's head.

In such arrangement, a manifold 1916 may be provided at the top of the patient's head to interconnect the tubes 1908.

3.5.5 Cover or Sock

In another embodiment, one or more portions of the frame, inlet tube, and/or head support may include a cover or sock to improve aesthetics and/or comfort.

3.6 InnoMed Technologies' Nasal-Aire™

FIGS. 31-1 and 31-2 illustrate another known mask 2000 commercially sold by InnoMed Technologies under the name of Nasal-Aire™. As illustrated, the mask 2000 includes a nasal interface 2004 provided to the patient's nose in use, inlet tubes 2008 provided to the respective sides of the nasal interface 2004 to deliver breathable gas to the patient, a manifold 2006 to interconnect the inlet tubes 2008, and a head strap 2005 to maintain the mask 2000 in a desired position on the patient's face.

3.6.0 Improvements/Alternative Arrangements

The following embodiments describe improvements and/or alternative arrangements of InnoMed Technologies' Nasal-Aire™ mask to enhance respiratory therapy.

3.6.1 Collapsible Tubes

The inlet tubes of the Nasal-Aire™ mask are substantially non-collapsible and/or crush-resistant. In an alternative embodiment, the inlet tubes may be replaced with collapsible conduits adapted to deliver breathable gas and stabilize the nasal interface on the patient's face. The collapsible conduits may include one or more of the collapsible tube properties described above. For example, each conduit may be provided with a rigidizer and/or each conduit may have a general D-shaped cross-section.

3.6.2 Back Strap

In an embodiment, as shown in FIG. 31-3, the mask may include a back strap 2009 rather than a full head strap to maintain the mask in a desired position on the patient's face. The back strap 209 may include one or more of the back strap properties described above.

3.6.3 Foam Seal

The Nasal-Aire™ mask includes a nasal interface constructed of a silicone material. In an alternative embodiment, as shown in FIG. 31-4, the nasal interface may be a foam nasal interface 2004F constructed of a foam material F. The foam material F may include one or more of the foam properties described above, e.g., visco-elastic, un-skinned, etc.

3.6.4 Manifold

The manifold of the Nasal-Aire™ mask includes a relatively rigid, one-piece, plastic structure. In an alternative embodiment, the manifold may be constructed of more than one material, e.g., rigid portion and semi-rigid portion, to improve comfort and/or aesthetics.

In another embodiment, the manifold may be positioned on the patient's head, rather than hang downwardly from the patient's head.

A preferred interfacing structure according to an embodiment of the invention utilizes foam having properties as set forth in FIG. 14-1. Known sealing interfaces have quite different bulk properties, for example, a typical silicone has a density in the range of 1050 to 1150 kg/m{circumflex over ( )}3, a tear strength of 20 to 40 N/mm, a tensile strength of approximately 10 Mpa, an elongation at break of 600%, a 40 Shore A hardness, hysteresis of less than about 5%, a resilience of approximately 40 to 50%, and an air permeability of 0.

While the invention has been described in connection with what are presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Also, the various embodiments described above may be implemented in conjunction with other embodiments, e.g., aspects of one embodiment may be combined with aspects of another embodiment to realize yet other embodiments. Further, each independent feature or component of any given assembly may constitute an additional embodiment. In addition, while the invention has particular application to patients who suffer from OSA, it is to be appreciated that patients who suffer from other illnesses (e.g., congestive heart failure, diabetes, morbid obesity, stroke, barriatric surgery, etc.) can derive benefit from the above teachings. Moreover, the above teachings have applicability with patients and non-patients alike in non-medical applications. 

What is claimed is:
 1. A mask system for providing a supply of air from a source of air at positive pressure to a patient for treatment of sleep disordered breathing, the mask system comprising: an interfacing structure configured to engage the patient's nose; and two inlet conduits detachably connectable to the interfacing structure and adapted to deliver the supply of air to the interfacing structure, each inlet conduit being adapted to extend from an upper portion of the patient's head, along a respective side of the patient's face between an eye and ear of the patient, and to the interfacing structure, each inlet conduit having a bottom portion adjacent the interfacing structure and a top portion in fluid communication with a supply of pressurized air, wherein, in a cross-sectional view, each inlet conduit has a contact portion configured to, in use, engage the patient's skin, wherein, in said cross-sectional view, a section of the contact portion has a wall thickness that is less than a wall thickness of the inlet conduit in a first side portion of the inlet conduit, and wherein each inlet conduit is structured and configured, without anti-crush ribs on an inside surface thereof, to: a) have sufficient strength to maintain an open state without being pressurized; and b) collapse, in use, under the weight of the patient's head to substantially prevent the flow of air, along at least selected sections of the inlet conduit.
 2. The mask system of claim 1, wherein a cross-sectional height of each inlet conduit varies along its length.
 3. The mask system of claim 2, wherein each inlet conduit has a cross-section that varies along its length such that a first cross-section at a first position along the length of the inlet conduit from the top portion to the bottom portion is different from a second cross-section at a second position along the length of the inlet conduit, and a third cross-section at a third position along the length of the inlet conduit is different from the first cross-section and the second cross-section, wherein the second position is located along the length of the inlet conduit at a position that is closer to the bottom portion of the inlet conduit than is the first position, and the third position is located along the length of the inlet conduit at a position that is closer to the bottom portion of the inlet conduit than is the second position, and wherein a width of the inlet conduit at the second position is less than a width of the inlet conduit at the first position, and a width of the inlet conduit at the third position is less than a width of the inlet conduit at the second position.
 4. The mask system of claim 3, wherein the first position along the length of the inlet conduit is configured to engage the upper portion of the patient's head.
 5. The mask system of claim 3, wherein a height of the inlet conduit at the second positon is greater than a height of the inlet conduit at the first position, and a height of the inlet conduit at the third position is greater than a height of the inlet conduit at the second position.
 6. The mask system of claim 1, wherein the cross-section of each inlet conduit varies along its length while the hydraulic diameter remains substantially constant.
 7. The mask system of claim 1, wherein each inlet conduit has a generally D-shaped cross-section.
 8. The mask system of claim 1, wherein each inlet conduit forms a one-piece silicone structure from the top portion to the bottom portion.
 9. The mask system of claim 1, further comprising a back strap extending between the two inlet conduits and adapted to engage a back of the patient's head, the back strap having an adjustable length.
 10. The mask system of claim 9, wherein the back strap comprises elastic properties.
 11. The mask system of claim 1, wherein the interfacing structure includes a silicone or foam interface with a single orifice arranged to engage and seal with the underside of the patient's nose.
 12. The mask system of claim 1, further comprising a manifold adapted to fluidly connect the two inlet conduits with the source of air, the manifold including swiveling features.
 13. The mask system of claim 12, wherein the manifold is configured to move relative to the inlet conduits in a swiveling manner.
 14. The mask system of claim 1, wherein each of the two inlet conduits is structured and configured to: a) cooperate with the other conduit such that pressurized air from the source of air is delivered to the interfacing structure via one or both of the inlet conduits even if one of the inlet conduits assumes an at least partially collapsed configuration.
 15. The mask system of claim 1, further comprising two rigid end portions, each rigid end portion being provided to an end of a respective one of the inlet conduits, to facilitate connection of the inlet conduits to the interfacing structure, the two rigid end portions being more rigid than the two inlet conduits.
 16. The mask system of claim 15, wherein each rigid end portion is co-molded with a respective one of the inlet conduits.
 17. The mask system of claim 1, further comprising: two rigid end portions, each rigid end portion being provided to an end of a respective one of the inlet conduits, to facilitate connection of the inlet conduits to the interfacing structure, the two rigid end portions being more rigid than the two inlet conduits; a back strap extending between the two inlet conduits and adapted to engage the back of the patient's head; and a manifold adapted to fluidly connect the two inlet conduits with the source of air, the manifold including swiveling features, wherein each inlet conduit forms a one-piece silicone structure from the top portion to the bottom portion, wherein each rigid end portion is co-molded with a respective one of the inlet conduits and has a tubular shape, wherein a length of the back strap is selectively adjustable, and the back strap includes hook and loop material, wherein the back strap is comprised of a different material than the inlet conduits, wherein the manifold is configured to move relative to the inlet conduits in a swiveling manner, and wherein the interfacing structure includes a silicone or foam interface to engage and seal with the underside of the patient's nose.
 18. The mask system of claim 1, wherein said section of the contact portion is a central section of the contact portion.
 19. The mask system of claim 1, wherein, in said cross-sectional view, the wall thickness of the section of the contact portion is less than a wall thickness of the inlet conduit at a second side portion of the inlet conduit, the second side portion being opposite the first side portion.
 20. The mask system of claim 19, wherein, in said cross-sectional view, each inlet conduit has a non-patient contacting portion opposite the contact portion that is not arranged to contact the patient's skin when the mask system is worn, and wherein the first side portion and the second side portion of each inlet conduit are disposed at opposing sides of the inlet conduit and between the contact portion and the non-patient contacting portion of the inlet conduit.
 21. A respiratory system for delivering a supply of air at positive pressure to a patient for treatment of sleep disordered breathing, the respiratory system comprising: the mask system of claim 1; and a positive pressure device to provide a supply of air at positive pressure to the mask system.
 22. A mask system for providing a supply of air from a source of air at positive pressure to a patient for treatment of sleep disordered breathing, the mask system comprising: an interfacing structure configured to engage the patient's nose; and two inlet conduits detachably connectable to the interfacing structure and adapted to deliver the supply of air to the interfacing structure, each inlet conduit being adapted to extend from an upper portion of the patient's head, along a respective side of the patient's face between the patient's eye and ear, and to the interfacing structure, each inlet conduit having a bottom portion adjacent the interfacing structure and a top portion in fluid communication with a supply of pressurized air, wherein, in a cross-sectional view, each inlet conduit has 1) a contact portion configured to, in use, engage the patient's skin, and 2) a non-patient contacting portion opposite the contact portion that is not arranged to, in use, contact the patient's skin, wherein, in said cross-sectional view, a first side portion of each the inlet conduit has a wall thickness that is not less than a wall thickness at any point along the non-patient contacting portion on the inlet conduit, and wherein each inlet conduit is structured without anti-crush ribs on an inside surface thereof, each inlet conduit being configured to: a) have sufficient strength to maintain an open state without being pressurized; and b) collapse, in use, under the weight of the patient's head to substantially prevent the flow of air, along at least selected sections of the inlet conduit.
 23. The mask system of claim 22, wherein the first side portion is disposed between the contact portion and the non-patient contacting portion of the inlet conduit.
 24. The mask system of claim 22, wherein a second side portion of each inlet conduit has a wall thickness that is not less than a wall thickness at any point along the non-patient contacting portion on the inlet conduit, wherein the first side portion and the second side portion are disposed at opposing sides of the inlet conduit and between the contact portion and the non-patient contacting portion of the inlet conduit.
 25. The mask system of claim 22, wherein a cross-sectional height of each inlet conduit varies along its length, and wherein each inlet conduit has a generally D-shaped cross-section.
 26. The mask system of claim 22, wherein each inlet conduit forms a one-piece silicone structure from the top portion to the bottom portion.
 27. The mask system of claim 22, further comprising a back strap extending between the two inlet conduits and adapted to engage a back of the patient's head, the back strap having an adjustable length.
 28. The mask system of claim 22, wherein the interfacing structure includes a silicone or foam interface with a single orifice arranged to engage and seal with the underside of the patient's nose.
 29. The mask system of claim 22, further comprising a manifold adapted to fluidly connect the two inlet conduits with the source of air, the manifold including swiveling features.
 30. A respiratory system for delivering a supply of air at positive pressure to a patient for treatment of sleep disordered breathing, the respiratory system comprising: the mask system of claim 22; and a positive pressure device to provide a supply of air at positive pressure to the mask system. 